Your search keyword '"Mark Eckart"' showing total 49 results

1. Observation of Hydrodynamic Flows in Imploding Fusion Plasmas on the National Ignition Facility

Author

Mark Eckart, Laura Robin Benedetti, Shahab Khan, J. D. Kilkenny, Leonard Jarrott, Brian Spears, David Schlossberg, J. E. Field, Christopher Young, Ryan Nora, M. Gatu Johnson, Daniel Casey, A. J. Mackinnon, W. W. Hsing, E. P. Hartouni, A. S. Moore, Robert Hatarik, D. H. Munro, Otto Landen, Sabrina Nagel, P. K. Patel, B. J. MacGowan, David N. Fittinghoff, Petr Volegov, R. M. Bionta, Arthur Pak, Gary Grim, B. Bachmann, K. D. Meaney, and V. Geppert-Kleinrath

Subjects

Physics, Jet (fluid), General Physics and Astronomy, Mechanics, Laser, Neutron spectroscopy, law.invention, Physics::Fluid Dynamics, law, Neutron, National Ignition Facility, Anisotropy, Inertial confinement fusion, Doppler broadening

Abstract

Inertial confinement fusion implosions designed to have minimal fluid motion at peak compression often show significant linear flows in the laboratory, attributable per simulations to percent-level imbalances in the laser drive illumination symmetry. We present experimental results which intentionally varied the mode 1 drive imbalance by up to 4% to test hydrodynamic predictions of flows and the resultant imploded core asymmetries and performance, as measured by a combination of DT neutron spectroscopy and high-resolution x-ray core imaging. Neutron yields decrease by up to 50%, and anisotropic neutron Doppler broadening increases by 20%, in agreement with simulations. Furthermore, a tracer jet from the capsule fill-tube perturbation that is entrained by the hot-spot flow confirms the average flow speeds deduced from neutron spectroscopy.

Published

2021

2. 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

3. The five line-of-sight neutron time-of-flight (nToF) suite on the National Ignition Facility (NIF)

Author

Gary Grim, E Mariscal, J. M. Gjemso, L Ma, A. S. Moore, C. Waltz, J. Carrera, Mark Eckart, E. P. Hartouni, J. D. Kilkenny, Shaun Kerr, D. A. Barker, and David Schlossberg

Subjects

010302 applied physics, Physics, Implosion, Scintillator, 01 natural sciences, Collimated light, 010305 fluids & plasmas, Nuclear physics, Time of flight, Physics::Plasma Physics, 0103 physical sciences, Neutron, National Ignition Facility, Instrumentation, Inertial confinement fusion, Cherenkov radiation

Abstract

Measurement of the neutron spectrum from inertial confinement fusion implosions is one of the primary diagnostics of implosion performance. Analysis of the spectrum gives access to quantities such as neutron yield, hot-spot velocity, apparent ion temperature, and compressed fuel ρr through measurement of the down-scatter ratio. On the National Ignition Facility, the neutron time-of-flight suite has been upgraded to include five independent, collimated lines of sight, each comprising a high dynamic range bibenzyl/diphenylacetylene-stilbene scintillator [R. Hatarik et al., Plasma Fusion Res. 9, 4404104 (2014)] and high-speed fused silica Cherenkov detectors [A. S. Moore et al., Rev. Sci. Instrum. 89, 10I120 (2018)].

Published

2021

4. Neutron Time-of-Flight Measurements of Charged-Particle Energy Loss in Inertial Confinement Fusion Plasmas

Author

M. Gatu Johnson, A. J. Mackinnon, Frank Graziani, Wolfgang Stoeffl, S. Le Pape, Nathan Meezan, Laurent Divol, D. H. Schneider, D. A. Shaughnessy, James McNaney, L. F. Berzak Hopkins, Gary Grim, E. P. Hartouni, Mark Eckart, Robert Hatarik, Shahab Khan, S. P. Hatchett, C. B. Yeamans, A. K. Hayes, H. G. Rinderknecht, J. P. Knauer, Stephanie Hansen, Dirk O. Gericke, Daniel Sayre, J. A. Caggiano, Alex Zylstra, C. J. Cerjan, and S. M. Sepke

Subjects

Physics, Thermonuclear fusion, General Physics and Astronomy, Magnetic confinement fusion, Implosion, Fusion power, 01 natural sciences, Charged particle, Nuclear physics, 0103 physical sciences, Neutron, 010306 general physics, National Ignition Facility, Inertial confinement fusion, QC

Abstract

Neutron spectra from secondary ^{3}H(d,n)α reactions produced by an implosion of a deuterium-gas capsule at the National Ignition Facility have been measured with order-of-magnitude improvements in statistics and resolution over past experiments. These new data and their sensitivity to the energy loss of fast tritons emitted from thermal ^{2}H(d,p)^{3}H reactions enable the first statistically significant investigation of charged-particle stopping via the emitted neutron spectrum. Radiation-hydrodynamic simulations, constrained to match a number of observables from the implosion, were used to predict the neutron spectra while employing two different energy loss models. This analysis represents the first test of stopping models under inertial confinement fusion conditions, covering plasma temperatures of k_{B}T≈1-4 keV and particle densities of n≈(12-2)×10^{24} cm^{-3}. Under these conditions, we find significant deviations of our data from a theory employing classical collisions whereas the theory including quantum diffraction agrees with our data.

Published

2019

5. 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

6. Proof-of-concept of a neutron time-of-flight ellipsoidal detector

Author

David Schlossberg, K. D. Hahn, Shaun Kerr, Alastair Moore, J. M. Gjemso, E. P. Hartouni, M. Rubery, J. Jeet, Mark Eckart, and E Mariscal

Subjects

Physics, Physics::Instrumentation and Detectors, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Detector, Scintillator, Time of flight, Optics, Radiator (engine cooling), Neutron, business, National Ignition Facility, Instrumentation, Inertial confinement fusion, Cherenkov radiation

Abstract

The time-resolved measurement of neutrons emitted from nuclear implosions at inertial confinement fusion facilities is used to characterize the fusing plasma. Several significant quantities are routinely measured by neutron time-of-flight (nToF) detectors in these experiments. Current nToF detectors use scintillators as well as solid-state Cherenkov radiators. The latter has an inherently faster time response and can provide a co-registered γ-ray measurement as well as improved precision in the bulk hot-spot velocity. This work discusses a nToF ellipsoidal detector that also utilizes a solid-state Cherenkov radiator. The detector has the potential to achieve a fast instrument response function allowing for characterization of the γ-ray burn history as well as the ability to field the detector closer to the fusion source. Proof-of-concept testing of the nToF ellipsoidal detector has been conducted at the National Ignition Facility using commercial optics. A time-resolved neutron signal has been measured from the diagnostic. Preliminary simulations corroborate the results.

Published

2021

7. Characterization of photodetector temporal response for neutron time-of-flight (nToF) diagnostics at the National Ignition Facility

Author

J M Gordon, Mark Eckart, Gary Grim, Robert Hatarik, P. Datte, E. P. Hartouni, David Schlossberg, C E Durand, and Alastair Moore

Subjects

010302 applied physics, Physics, Photomultiplier, business.industry, Detector, Photodetector, 01 natural sciences, 010305 fluids & plasmas, Photodiode, law.invention, Time of flight, Optics, law, 0103 physical sciences, Microchannel plate detector, business, National Ignition Facility, Instrumentation, Impulse response

Abstract

The temporal response of a microchannel plate photomultiplier tube used in the suite of neutron time of flight (nToF) diagnostics at the National Ignition Facility has been characterized to reduce uncertainty in, and understanding of, shot parameters obtained from nTOF data. A short pulse laser, neutral density glass filters, and electrical attenuators were used to gather statistically significant samples of photodetector impulse response functions (IRF) in rapid succession. Individual components have been absolutely calibrated to minimize systematic uncertainties. The zeroth (collected charge), first (transit time), and second central moments (transit time spread) of the IRF were calculated as either the bias voltage or the amount of light incident on the detector was varied. Timing reference was provided by a monitor photodiode viewing a pickoff of the incident laser pulse. The primary sources of uncertainty are jitter in the monitor photodiode and the statistical variation across our measurement period. The spreads in the first moment, with respect to the timing photodiode, and the square root of the second central moment were found to be less than 50 ps and 150 ps, respectively.

Published

2018

8. Using multiple neutron time of flight detectors to determine the hot spot velocity

Author

E. P. Hartouni, Ryan Nora, Mark Eckart, David Schlossberg, Gary Grim, Robert Hatarik, Alastair Moore, and Brian Spears

Subjects

Physics, business.industry, Hot spot (veterinary medicine), Plasma, 01 natural sciences, 010305 fluids & plasmas, Time of flight, Optics, Physics::Plasma Physics, 0103 physical sciences, Neutron detection, Plasma diagnostics, Neutron, 010306 general physics, National Ignition Facility, business, Instrumentation, Inertial confinement fusion

Abstract

An important diagnostic value of a shot at the National Ignition Facility is the resultant center-of-mass motion of the imploding capsule. This residual velocity reduces the efficiency of converting laser energy into plasma temperature. A new analysis method extracts the effective hot spot motion by using information from multiple neutron time-of-flight (nToF) lines-of-sight (LoSs). This technique fits a near Gaussian spectrum to the nToF scope traces and overcomes reliance on models to relate the plasma temperature to the mean energy of the emitted neutrons. This method requires having at least four nToF LoSs. The results of this analysis will be compared to an approach where each LoS is analyzed separately and a model is used to infer the mean energy of the emitted neutrons.

Published

2018

9. Radiation effects on active camera electronics in the target chamber at the National Ignition Facility

Author

D. Hargrove, Mark Eckart, P. Datte, Perry M. Bell, Arthur C. Carpenter, M. Dayton, Hesham Khater, and Anastacia M. Manuel

Subjects

010308 nuclear & particles physics, Computer science, Nuclear engineering, Hardware_PERFORMANCEANDRELIABILITY, Radiation, 01 natural sciences, Upset, Flash (photography), visual_art, 0103 physical sciences, Electronic component, visual_art.visual_art_medium, Neutron source, Neutron, Electronics, 010306 general physics, National Ignition Facility, Simulation

Abstract

The National Ignition Facility’s (NIF) harsh radiation environment can cause electronics to malfunction during high-yield DT shots. Until now there has been little experience fielding electronic-based cameras in the target chamber under these conditions; hence, the performance of electronic components in NIF’s radiation environment was unknown. It is possible to purchase radiation tolerant devices, however, they are usually qualified for radiation environments different to NIF, such as space flight or nuclear reactors. This paper presents the results from a series of online experiments that used two different prototype camera systems built from non-radiation hardened components and one commercially available camera that permanently failed at relatively low total integrated dose. The custom design built in Livermore endured a 5 × 1015 neutron shot without upset, while the other custom design upset at 2 × 1014 neutrons. These results agreed with offline testing done with a flash x-ray source and a 14 MeV neutron source, which suggested a methodology for developing and qualifying electronic systems for NIF. Further work will likely lead to the use of embedded electronic systems in the target chamber during high-yield shots.

Published

2017

10. Progress of indirect drive inertial confinement fusion in the United States

Author

D. Hoover, John Kline, J. A. Caggiano, D. H. Edgell, Omar Hurricane, Alex Zylstra, David Strozzi, Rebecca Dylla-Spears, J. E. Field, Michael Farrell, Laurent Divol, Andrew MacPhee, E. Piceno, O. S. Jones, Tammy Ma, C. Kong, E. J. Bond, Darwin Ho, Steven H. Batha, Steve MacLaren, E. L. Dewald, Sebastien LePape, S. Khan, James Ross, Daniel Sayre, Robert Tipton, Monika M. Biener, B. Cagadas, Jay D. Salmonson, C. F. Walters, S. A. Johnson, David N. Fittinghoff, A. Nikroo, Harry Robey, Ep. Hartouni, D. K. Bradley, H. Huang, Laurent Masse, Petr Volegov, Michael Stadermann, Hans W. Herrmann, Jürgen Biener, S. W. Haan, Don Bennett, Rpj Town, S. M. Sepke, James McNaney, C. J. Cerjan, Kevin Henderson, R. M. Bionta, V. A. Smalyuk, Nathan Meezan, N. Izumi, M. Schneider, M.R. Sacks, Louisa Pickworth, Brian Haines, Jose Milovich, A. V. Hamza, W. W. Hsing, J. D. Kilkenny, E. Woerner, P. K. Patel, Mark Eckart, Laura Robin Benedetti, B. E. Yoxall, Carlos E. Castro, J. D. Moody, J. D. Sater, B. J. Kozioziemski, M. Gatu Johnson, A. J. Mackinnon, Brian Spears, R. Seugling, David C. Clark, Robert Hatarik, Jeremy Kroll, S. A. Yi, Denise Hinkel, Cliff Thomas, Joseph Ralph, M. Wang, Otto Landen, T. Braun, J.F. Merrill, C. B. Yeamans, Matthias Hohenberger, M. Schoff, Carl Wilde, Larry L. Peterson, M. J. Edwards, Tilo Döppner, Gary Grim, J. R. Rygg, Arthur Pak, George A. Kyrala, Suhas Bhandarkar, Wolfgang Stoeffl, Debra Callahan, Neal Rice, M. Hoppe, and L. F. Berzak Hopkins

Subjects

Nuclear physics, Physics, Nuclear and High Energy Physics, Condensed Matter Physics, Inertial confinement fusion

Abstract

Indirect drive converts high power laser light into x-rays using small high-Z cavities called hohlraums. X-rays generated at the hohlraum walls drive a capsule filled with deuterium–tritium (DT) fuel to fusion conditions. Recent experiments have produced fusion yields exceeding 50 kJ where alpha heating provides ~3× increase in yield over PdV work. Closing the gaps toward ignition is challenging, requiring optimization of the target/implosions and the laser to extract maximum energy. The US program has a three-pronged approach to maximize target performance, each closing some portion of the gap. The first item is optimizing the hohlraum to couple more energy to the capsule while maintaining symmetry control. Novel hohlraum designs are being pursued that enable a larger capsule to be driven symmetrically to both reduce 3D effects and increase energy coupled to the capsule. The second issue being addressed is capsule stability. Seeding of instabilities by the hardware used to mount the capsule and fill it with DT fuel remains a concern. Work reducing the impact of the DT fill tubes and novel capsule mounts is being pursed to reduce the effect of mix on the capsule implosions. There is also growing evidence native capsule seeds such as a micro-structure may be playing a role on limiting capsule performance and dedicated experiments are being developed to better understand the phenomenon. The last area of emphasis is the laser. As technology progresses and understanding of laser damage/mitigation advances, increasing the laser energy seems possible. This would increase the amount of energy available to couple to the capsule, and allow larger capsules, potentially increasing the hot spot pressure and confinement time. The combination of each of these focus areas has the potential to produce conditions to initiate thermo-nuclear ignition.

Published

2019

11. Uncertainty analysis of signal deconvolution using a measured instrument response function

Author

Robert Hatarik, J. A. Caggiano, C. J. Cerjan, D. H. Munro, E. P. Hartouni, Mark Eckart, B Beeman, Daniel Sayre, Thomas G. Phillips, Alastair Moore, and Gary Grim

Subjects

010302 applied physics, Physics, Bayesian probability, Parameterized complexity, Observable, Function (mathematics), 01 natural sciences, Signal, 010305 fluids & plasmas, High Energy Physics::Theory, Theoretical physics, 0103 physical sciences, Deconvolution, National Ignition Facility, Instrumentation, Algorithm, Uncertainty analysis

Abstract

A common analysis procedure minimizes the ln-likelihood that a set of experimental observables matches a parameterized model of the observation. The model includes a description of the underlying physical process as well as the instrument response function (IRF). In the case investigated here, the National Ignition Facility (NIF) neutron time-of-flight (nTOF) spectrometers, the IRF is constructed from measurements and models. IRF measurements have a finite precision that can make significant contributions to determine the uncertainty estimate of the physical model’s parameters. We apply a Bayesian analysis to properly account for IRF uncertainties in calculating the ln-likelihood function used to find the optimum physical parameters.

Published

2016

12. Impulse responses of visible phototubes used in National Ignition Facility neutron time of flight diagnostics

Author

W. Thompson, A. S. Moore, Mark Eckart, G. Vergel de Dios, and P. Datte

Subjects

010302 applied physics, Physics, Photomultiplier, Scintillation, business.industry, Impulse (physics), 01 natural sciences, 010305 fluids & plasmas, Photodiode, law.invention, Time of flight, Optics, law, 0103 physical sciences, Neutron, National Ignition Facility, business, Instrumentation, Impulse response

Abstract

Neutron-induced visible scintillation in neutron time of flight (NToF) diagnostics at the National Ignition Facility (NIF) is measured with 40 mm single stage micro-channel plate photomultipliers and a 40 mm vacuum photodiode, outside the neutron line of sight. In NIF experiments with 14 MeV neutron yields above Y > 10 × 1015 these tubes are configured to deliver of order 1 nC of charge in the nominally 5 ns NToF into a 50 Ω load. We have examined a number of 40 mm tubes manufactured by Photek Ltd. of St. Leonards on Sea, UK, to determine possible changes in the instrument impulse response as a function of signal charge delivered in 1 ns. Precision NToF measurements at approximately 20 m require that we characterize changes in the impulse response moments to

Published

2016

13. Calibration of scintillation-light filters for neutron time-of-flight spectrometers at the National Ignition Facility

Author

E. P. Hartouni, Robert Hatarik, F. A. Weber, J. A. Caggiano, Gary Grim, F Barbosa, V. N. DiPuccio, Daniel Sayre, and Mark Eckart

Subjects

010302 applied physics, Physics, Scintillation, Spectrometer, business.industry, Attenuation, Astrophysics::Instrumentation and Methods for Astrophysics, 01 natural sciences, 010305 fluids & plasmas, Time of flight, Optics, 0103 physical sciences, Calibration, Measuring instrument, Physics::Accelerator Physics, Neutron, National Ignition Facility, business, Instrumentation

Abstract

Sixty-four neutral density filters constructed of metal plates with 88 apertures of varying diameter have been radiographed with a soft x-ray source and CCD camera at National Security Technologies, Livermore. An analysis of the radiographs fits the radial dependence of the apertures’ image intensities to sigmoid functions, which can describe the rapidly decreasing intensity towards the apertures’ edges. The fitted image intensities determine the relative attenuation value of each filter. Absolute attenuation values of several imaged filters, measured in situ during calibration experiments, normalize the relative quantities which are now used in analyses of neutron spectrometer data at the National Ignition Facility.

Published

2016

14. Indications of flow near maximum compression in layered deuterium-tritium implosions at the National Ignition Facility

Author

Mark Eckart, N. Meezan, A. L. Kritcher, P. T. Springer, P. K. Patel, E. J. Bond, D. H. Munro, V. Yu. Glebov, R. M. Bionta, Tammy Ma, J. D. Kilkenny, Joseph Ralph, E. P. Hartouni, Brian Spears, Daniel Sayre, J. P. Knauer, C. B. Yeamans, Daniel Casey, Debra Callahan, Robert Hatarik, Tilo Döppner, Gary Grim, R. D. Petrasso, Johan Frenje, Omar Hurricane, M. Gatu Johnson, A. J. Mackinnon, J. A. Caggiano, C. J. Cerjan, and Sebastien LePape

Subjects

Materials science, Attenuation, Isotropy, 01 natural sciences, 010305 fluids & plasmas, Ion, law.invention, Ignition system, Deuterium, Physics::Plasma Physics, law, 0103 physical sciences, Neutron, Tritium, Atomic physics, 010306 general physics, National Ignition Facility

Abstract

An accurate understanding of burn dynamics in implosions of cryogenically layered deuterium (D) and tritium (T) filled capsules, obtained partly through precision diagnosis of these experiments, is essential for assessing the impediments to achieving ignition at the National Ignition Facility. We present measurements of neutrons from such implosions. The apparent ion temperatures T_{ion} are inferred from the variance of the primary neutron spectrum. Consistently higher DT than DD T_{ion} are observed and the difference is seen to increase with increasing apparent DT T_{ion}. The line-of-sight rms variations of both DD and DT T_{ion} are small, ∼150eV, indicating an isotropic source. The DD neutron yields are consistently high relative to the DT neutron yields given the observed T_{ion}. Spatial and temporal variations of the DT temperature and density, DD-DT differential attenuation in the surrounding DT fuel, and fluid motion variations contribute to a DT T_{ion} greater than the DD T_{ion}, but are in a one-dimensional model insufficient to explain the data. We hypothesize that in a three-dimensional interpretation, these effects combined could explain the results.

Published

2016

15. A fused silica Cherenkov radiator for high precision time-of-flight measurement of DT γ and neutron spectra (invited)

Author

Mark Eckart, B Beeman, M. S. Rubery, Daniel Sayre, A. S. Moore, F Barbosa, Robert Hatarik, E. P. Hartouni, Gary Grim, David Schlossberg, J Root, and C. Waltz

Subjects

010302 applied physics, Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Detector, Implosion, Scintillator, 01 natural sciences, Neutron temperature, 010305 fluids & plasmas, Time of flight, Optics, 0103 physical sciences, Neutron, National Ignition Facility, business, Instrumentation, Cherenkov radiation

Abstract

A fused silica Cherenkov radiator has been implemented at the National Ignition Facility to provide a new high precision measurement of the time-of-flight spectrum of 14.1 MeV DT fusion neutrons. This detector enables a high precision (

Published

2018

16. Testing a Cherenkov neutron time-of-flight detector on OMEGA

Author

V. Yu. Glebov, David Schlossberg, T. C. Sangster, C. Stoeckl, E. P. Hartouni, Robert Hatarik, J. P. Knauer, Gary Grim, Mark Eckart, Chad Forrest, Susan Regan, and Alastair Moore

Subjects

010302 applied physics, Physics, Photomultiplier, Time of flight detector, Physics::Instrumentation and Detectors, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Detector, Astrophysics::Instrumentation and Methods for Astrophysics, Compton scattering, 01 natural sciences, Collimated light, 010305 fluids & plasmas, Optics, 0103 physical sciences, Neutron detection, Neutron, business, Instrumentation, Cherenkov radiation

Abstract

A Cherenkov neutron time-of-flight (nTOF) detector developed and constructed at Lawrence Livermore National Laboratory was tested at 13 m from the target in a collimated line of sight (LOS) and at 5.3 m from the target in the open space inside the OMEGA Target Bay. Neutrons interacting with the quartz rod generate gammas, which through Compton scattering produce relativistic electrons that give rise to Cherenkov light. A photomultiplier tube (PMT) transferred the Cherenkov light into an amplified electrical signal. The Cherenkov nTOF detector consists of an 8-mm-diam, 25-cm quartz hexagonal prism coupled with a Hamamatsu gated PMT R5916U-52. The tests were performed with DT direct-drive implosions with cryogenic and room-temperature targets, producing a wide range of neutron yields and ion temperatures. The results of the tests and comparison with other nTOF detectors on OMEGA are presented. In the collimated LOS at 13 m from the target, the Cherenkov nTOF detector demonstrated good precision measurement in both the yield and ion temperature for DT yields above 3 × 1013.

Published

2018

17. Uncertainty analysis of response functions and γ-backgrounds on Tion and t0 measurements from Cherenkov neutron detectors at the National Ignition Facility (NIF)

Author

M. S. Rubery, C. Waltz, Daniel Sayre, E. P. Hartouni, Mark Eckart, Gary Grim, B Beeman, Robert Hatarik, David Schlossberg, and A. S. Moore

Subjects

010302 applied physics, Physics, Physics::Instrumentation and Detectors, Cherenkov detector, Monte Carlo method, Detector, Radiation, 01 natural sciences, 010305 fluids & plasmas, law.invention, Nuclear physics, law, 0103 physical sciences, Neutron detection, Neutron, Instrumentation, Cherenkov radiation, Uncertainty analysis

Abstract

Cherenkov radiators deployed to measure the neutron time-of-flight spectrum have response times associated with the neutron transit across the detector and are free from long time response tails characteristic of scintillation detectors. The Cherenkov radiation results from simple physical processes which makes them amenable to high fidelity Monte Carlo simulation. The instrument response function of neutron time-of-flight systems is a major contributor to both the systematic and statistical uncertainties of the parameters used to describe these spectra; in particular, the first and second moments of these distributions are associated with arrival time, t0, and ion temperature, Tion. We present the results of uncertainty analysis showing the significant reduction of the uncertainty in determining these quantities in the Cherenkov detector system recently deployed at NIF. The increased sensitivity to gamma radiation requires additional consideration of the effect of this background to the uncertainties in both t0 and Tion.

Published

2018

18. Ab initio response functions for Cherenkov-based neutron detectors

Author

Robert Hatarik, Mark Eckart, E. P. Hartouni, David Schlossberg, B Beeman, Alastair Moore, M. S. Rubery, Gary Grim, Daniel Sayre, and C. Waltz

Subjects

Physics, Photomultiplier, Physics::Instrumentation and Detectors, Monte Carlo method, Ab initio, Scintillator, 01 natural sciences, 010305 fluids & plasmas, Computational physics, 0103 physical sciences, Neutron detection, Neutron, Microchannel plate detector, 010306 general physics, Instrumentation, Cherenkov radiation

Abstract

Neutron time-of-flight diagnostics at the NIF were recently outfitted with Cherenkov detectors. A fused silica radiator delivers sub-nanosecond response time and is optically coupled to a microchannel plate photomultiplier tube with gain from ∼1 to 104. Capitalizing on fast time response and gamma-ray sensitivity, these systems can provide better than 30 ps precision for measuring first moments of neutron distributions. Generation of ab initio instrument response functions (IRFs) is critical to meet the

Published

2018

19. First High-Convergence Cryogenic Implosion in a Near-Vacuum Hohlraum

Author

J. D. Moody, Michael Stadermann, Andrew MacPhee, George A. Kyrala, E. Woerner, J. A. Church, D. A. Callahan, Gary Grim, Daniel Sayre, Abbas Nikroo, T. Ma, Wolfgang Stoeffl, Laurent Divol, James Ross, L. F. Berzak Hopkins, D. Hoover, Mark Eckart, Laura Robin Benedetti, Robert Hatarik, M. Gatu Johnson, Richard Town, A. J. Mackinnon, Shahab Khan, Hans W. Herrmann, Frank E. Merrill, S. M. Sepke, J. A. Caggiano, Jeremy Kroll, Harry Robey, James McNaney, Rebecca Dylla-Spears, C. B. Yeamans, A. V. Hamza, H. Huang, E. P. Hartouni, Matthias Hohenberger, David C. Clark, J. D. Kilkenny, Carl Wilde, D. H. Edgell, Darwin Ho, P. K. Patel, M. J. Edwards, Tilo Döppner, Art Pak, Nobuhiko Izumi, Denise Hinkel, Cliff Thomas, Jose Milovich, R. M. Bionta, Joseph Ralph, Otto Landen, B. E. Yoxall, Michael Schneider, Nathan Meezan, J. Sater, S. Le Pape, Petr Volegov, N. Guler, C. J. Cerjan, David N. Fittinghoff, C. Wild, D. K. Bradley, B. J. Kozioziemski, J. E. Field, O. S. Jones, E. J. Bond, Juergen Biener, S. W. Haan, W. W. Hsing, and J. R. Rygg

Subjects

Physics, business.industry, General Physics and Astronomy, Implosion, Plasma, Laser, Symmetry (physics), Pulse (physics), law.invention, Nuclear physics, Optics, Physics::Plasma Physics, Hohlraum, law, Neutron, National Ignition Facility, business

Abstract

Recent experiments on the National Ignition Facility [M. J. Edwards et al., Phys. Plasmas 20, 070501 (2013)] demonstrate that utilizing a near-vacuum hohlraum (low pressure gas-filled) is a viable option for high convergence cryogenic deuterium-tritium (DT) layered capsule implosions. This is made possible by using a dense ablator (high-density carbon), which shortens the drive duration needed to achieve high convergence: a measured 40% higher hohlraum efficiency than typical gas-filled hohlraums, which requires less laser energy going into the hohlraum, and an observed better symmetry control than anticipated by standard hydrodynamics simulations. The first series of near-vacuum hohlraum experiments culminated in a 6.8 ns, 1.2 MJ laser pulse driving a 2-shock, high adiabat (α ~ 3.5) cryogenic DT layered high density carbon capsule. This resulted in one of the best performances so far on the NIF relative to laser energy, with a measured primary neutron yield of 1.8 X 10¹⁵ neutrons, with 20% calculated alpha heating at convergence ~27X.

Published

2015

20. Engineering architecture of the neutron Time-of-Flight (nToF) diagnostic suite at the National Ignition Facility

Author

Natalia Zaitseva, A. Pruyne, B. Talison, Arthur C. Carpenter, J. P. Knauer, Milton J. Shoup, Robert Hatarik, T. Buczek, J. A. Caggiano, M. Yeoman, James McNaney, Z. Zeid, Mark Eckart, R. Zacharias, Kenneth L. Marshall, T. J. Clancy, Michael J. Moran, T. Duffy, Stephan Friedrich, Brian Scott Rice, J. B. Worden, and V. Y. Glebov

Subjects

Physics, Photomultiplier, Scintillation, Time of flight, Optics, Physics::Instrumentation and Detectors, business.industry, Neutron, High voltage, Radiation, Scintillator, National Ignition Facility, business

Abstract

This paper describes the engineering architecture and function of the neutron Time-of-Flight (nToF) diagnostic suite installed on the National Ignition Facility (NIF) at Lawrence Livermore National Laboratory (LLNL). These instruments provide key measures of neutron yield, ion temperature, drift velocity, neutron bang-time, and neutron downscatter ratio. Currently, there are five nToFs on three collimated lines-of-site (LOS) from 18m to 27m from Target Chamber Center, and three positioned 4.5m from TCC, within the NIF Target Chamber but outside the vacuum and confinement boundary by use of re-entrant wells on three other LOS. NIF nToFs measure the time history and equivalent energy spectrum of reaction generated neutrons from a NIF experiment. Neutrons are transduced to electrical signals, which are then carried either by coaxial or Mach-Zehnder transmission systems that feed divider assemblies and fiducially timed digitizing oscilloscopes outside the NIF Target Bay (TB) radiation shield wall. One method of transduction employs a two-stage process wherein a neutron is converted to scintillation photons in hydrogen doped plastic (20x40mm) or bibenzyl crystals (280x1050mm), which are subsequently converted to an electrical signal via a photomultiplier tube or a photo-diode. An alternative approach uses a single-stage conversion of neutrons-to-electrons by use of a thin (0.25 to 2 mm) Chemical Vapor Deposition Diamond (CVDD) disc (2 to 24mm radius) under high voltage bias. In comparison to the scintillator method, CVDDs have fast rise and decay times (

Published

2014

21. 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

22. High-resolution measurements of the DT neutron spectrum using new CD foils in the Magnetic Recoil neutron Spectrometer (MRS) on the National Ignition Facility

Author

M. Schoff, J. D. Kilkenny, M. Hoppe, Daniel Casey, R. D. Petrasso, Robert Hatarik, H. Reynolds, M. Gatu Johnson, Mark Eckart, E. P. Hartouni, Gary Grim, C. K. Li, K. Skulina, Daniel Sayre, C. B. Yeamans, Johan Frenje, Fredrick Seguin, R. Bionta, and Michael Farrell

Subjects

010302 applied physics, Physics, Spectrometer, Physics::Instrumentation and Detectors, Orders of magnitude (temperature), 01 natural sciences, 010305 fluids & plasmas, Nuclear physics, Recoil, Deuterium, Physics::Plasma Physics, 0103 physical sciences, Neutron source, Neutron, National Ignition Facility, Instrumentation, Inertial confinement fusion

Abstract

The Magnetic Recoil neutron Spectrometer (MRS) on the National Ignition Facility measures the DT neutron spectrum from cryogenically layered inertial confinement fusion implosions. Yield, areal density, apparent ion temperature, and directional fluid flow are inferred from the MRS data. This paper describes recent advances in MRS measurements of the primary peak using new, thinner, reduced-area deuterated plastic (CD) conversion foils. The new foils allow operation of MRS at yields 2 orders of magnitude higher than previously possible, at a resolution down to ∼200 keV FWHM.

Published

2016

23. Design of a north pole Neutron Time-of-Flight (NTOF) system at NIF

Author

E. P. Hartouni, Daniel Sayre, M. Yeoman, T. J. Clancy, M Sampson, A Lee, H Y Khater, Mark Eckart, J. A. Caggiano, C Yeamans, F Barbosa, G Grim, and R Hatarik

Subjects

History, Physics::Instrumentation and Detectors, 020209 energy, 02 engineering and technology, Scintillator, 01 natural sciences, 010305 fluids & plasmas, Education, law.invention, Optics, law, 0103 physical sciences, 0202 electrical engineering, electronic engineering, information engineering, Neutron, Beam dump, Simulation, Physics, business.industry, Attenuation, Detector, Collimator, Computer Science Applications, Neutron spectroscopy, Time of flight, Physics::Accelerator Physics, business

Abstract

A north pole NTOF system for neutron spectroscopy is being implemented at the NIF. The design is centered around a fast scintillator with low mass housing fielded 21.6m from target chamber center at θ=18°,=304°. The line-of-sight (LOS) features a primary port collimator, two secondary collimators in the intervening concrete floors, and a beam dump with a backscatter shield. Because the detector is being fielded on the roof of the NIF building, diagnostic options such as optical and electrical attenuation are remotely controlled, saving setup time and increasing shot rate. The expected performance of the diagnostic is excellent with high sensitivity to both high-energy reaction-in-flight neutrons as well as lower energy down-scattered neutrons.

Published

2016

24. Nuclear Diagnostics at the National Ignition Facility, 2013-2015

Author

J. A. Church, R. D. Petrasso, D. A. Shaughnessy, J. A. Caggiano, J. P. Knauer, S. M. Sepke, H. G. Rinderknecht, Daniel Sayre, M. Gatu Johnson, D. L. Bleuel, A. J. Mackinnon, Frank E. Merrill, William S. Cassata, J. D. Kilkenny, Michael J. Moran, E. P. Hartouni, V. Yu. Glebov, R. M. Bionta, Chad Forrest, David N. Fittinghoff, P. M. Grant, N. Gharibyan, D. H. Schneider, Hans W. Herrmann, Gary Grim, J. A. Frenje, Kenton J. Moody, C. A. Velsko, Wolfgang Stoeffl, C. B. Yeamans, Robert Hatarik, Gary Wayne Cooper, Mark Eckart, C. J. Cerjan, T. W. Phillips, Hong Sio, E. R. Edwards, Petr Volegov, and S. A. Faye

Subjects

010302 applied physics, History, Nuclear engineering, media_common.quotation_subject, Neutron spectra, Time resolution, Art, 01 natural sciences, Archaeology, 010305 fluids & plasmas, Computer Science Applications, Education, 0103 physical sciences, Radiochemical analysis, National Ignition Facility, National laboratory, Crime detection, Laboratory for Laser Energetics, media_common

Abstract

C.B. Yeamans, W. Cassata, J.A. Church, D.N. Fittinghoff, M. Gatu Johnson, N. Gharibyan, R. Hatarik, D.B. Sayre, H.W. Sio, R.M. Bionta, D.L. Bleuel, J.A. Caggiano, C.J. Cerjan, G.W. Copper, M.J. Eckart, E.R. Edwards, S.A. Faye, C.J. Forrest, J.A. Frenje, V.Yu. Glebov, P.F. Grant, G.P. Grim, E.P. Hartouni, H.W. Herrmann, J.D. Kilkenny, J.P. Knauer, A.J. Mackinnon, F.E. Merrill, K.J. Moody, M.J. Moran, R.D. Petrasso, T.W. Phillips, H.G. Rinderknecht, D. H. G. Schneider, S.M. Sepke, D.A. Shaughnessy, W. Stoeffl, C.A. Velsko, P. Volegov 1 Lawrence Livermore National Laboratory, Livermore, California, USA 2 General Atomics, San Diego, California, USA 3 Los Alamos National Laboratory, Los Alamos, New Mexico, USA 4 Massachusetts Institute of Technology, Cambridge, Massachusetts, USA 5 University of California, Berkeley, Berkeley, California, USA 6 University of New Mexico, Albuquerque, New Mexico, USA 7 University of Rochester, Laboratory for Laser Energetics, Rochester, New York, USA yeamans1@llnl.gov

Published

2016

25. Simulations of symcap and layered NIF experiments with top/bottom laser asymmetry to impose P1 drive on capsules

Author

Brian Spears, Daniel Sayre, Debra Callahan, Sabrina Nagel, Mark Eckart, Jose Milovich, Richard Town, J. P. Knauer, Frank E. Merrill, D. T. Casey, B Pollock, Harry Robey, J. A. Caggiano, Chris Weber, S. P. Hatchett, Denise Hinkel, A. L. Kritcher, N. Izumi, Robert Hatarik, O. S. Jones, C. B. Yeamans, David N. Fittinghoff, S. Khan, D. L. Bleuel, D. K. Bradley, D. C. Eder, T. Ma, Gary Grim, and A. Pak

Subjects

Physics, History, Yield (engineering), business.industry, media_common.quotation_subject, Laser, 01 natural sciences, Asymmetry, 010305 fluids & plasmas, Computer Science Applications, Education, law.invention, Shock (mechanics), Time of flight, Optics, law, Hohlraum, 0103 physical sciences, Neutron, Area density, 010306 general physics, business, media_common

Abstract

Integrated hohlraum/capsule post-shot simulation of the first full-scale cryogenic layered-DT experiment with top/bottom laser asymmetries of 8% is discussed. The imposed P1 Legendre mode drive on the capsule results in downward velocity of 85 ± 15 km/s as measured by neutron time of flight (NTOF) diagnostics and x-ray imagers, which is in excellent agreement with the calculated velocity of 87 km/s. The measured DT yield is approximately 30% less than the average of two comparable shots using the same 4 shock HiFoot pulse shape without drive asymmetry. The calculated DT yield of 5.0e15 is very close to the measured value of 4.86e15 for the shot with drive asymmetry, which implies that P1 effects dominate yield reduction. The neutron activation diagnostics (NADs) give clear indication of higher areal density in the direction of the north pole in excellent agreement with calculations. Integrated post-shot simulation of an earlier symcap (capsule with appropriate ablator thicknesses to act as a surrogate for an ignition capsule) experiment with laser asymmetries show that calculated neutron-wighted velocity is a strong function of capsule shape.

Published

2016

26. Neutron spectrometry--an essential tool for diagnosing implosions at the National Ignition Facility (invited)

Author

Arthur C. Carpenter, J. Magoon, V. A. Smalyuk, Scott Sepke, C. J. Cerjan, C. K. Li, R. D. Petrasso, Gary Grim, J. A. Frenje, M. J. Edwards, Joseph Ralph, Christian Stoeckl, Siegfried Glenzer, O. S. Jones, Mark Eckart, Otto Landen, George A. Kyrala, M. Gatu Johnson, R. C. Ashabranner, R. J. Leeper, A. J. Mackinnon, M. McKernan, Daniel Jasion, Tammy Ma, D. H. Munro, J. A. Caggiano, Bruce Remington, E. J. Bond, S. P. Hatchett, V. Yu. Glebov, C. B. Yeamans, P. T. Springer, Art J. Nelson, A. Nikroo, George L. Morgan, D. T. Casey, J. D. Kilkenny, Thomas J. Murphy, Milton J. Shoup, D. L. Bleuel, Michael J. Moran, R. Paguio, Gary Wayne Cooper, F. H. Séguin, S. Le Pape, James McNaney, J. P. Knauer, J. R. Rygg, Michael Farrell, Chimpén Ruiz, S. W. Haan, Edward I. Moses, Brian Spears, Robert Hatarik, E. P. Hartouni, R. M. Bionta, H.-S. Park, Stephan Friedrich, R. Betti, T. J. Clancy, John Kline, Tilo Doeppner, T. C. Sangster, and R. A. Lerche

Subjects

Nuclear physics, Physics, Spectrometer, Measuring instrument, Implosion, Neutron detection, Neutron, National Ignition Facility, Instrumentation, Inertial confinement fusion, Neutron spectroscopy

Abstract

DT neutron yield (Y(n)), ion temperature (T(i)), and down-scatter ratio (dsr) determined from measured neutron spectra are essential metrics for diagnosing the performance of inertial confinement fusion (ICF) implosions at the National Ignition Facility (NIF). A suite of neutron-time-of-flight (nTOF) spectrometers and a magnetic recoil spectrometer (MRS) have been implemented in different locations around the NIF target chamber, providing good implosion coverage and the complementarity required for reliable measurements of Y(n), T(i), and dsr. From the measured dsr value, an areal density (ρR) is determined through the relationship ρR(tot) (g∕cm(2)) = (20.4 ± 0.6) × dsr(10-12 MeV). The proportionality constant is determined considering implosion geometry, neutron attenuation, and energy range used for the dsr measurement. To ensure high accuracy in the measurements, a series of commissioning experiments using exploding pushers have been used for in situ calibration of the as-built spectrometers, which are now performing to the required accuracy. Recent data obtained with the MRS and nTOFs indicate that the implosion performance of cryogenically layered DT implosions, characterized by the experimental ignition threshold factor (ITFx), which is a function of dsr (or fuel ρR) and Y(n), has improved almost two orders of magnitude since the first shot in September, 2010.

Published

2012

27. South pole bang-time diagnostic on the National Ignition Facility (invited)

Author

Christian Stoeckl, T. C. Sangster, E. J. Bond, G. LaCaille, Andrew MacPhee, A. J. Mackinnon, D. H. Edgell, V. Yu. Glebov, J. Parker, S. Burns, J. R. Kimbrough, J. Magoon, D. K. Bradley, Mark Eckart, Milton J. Shoup, T. Thomas, J. D. Kilkenny, D. S. Hey, John R. Celeste, and Debra Callahan

Subjects

Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, X-ray optics, Laser, law.invention, Wavelength, Optics, Highly oriented pyrolytic graphite, Hohlraum, law, Plasma diagnostics, National Ignition Facility, business, Instrumentation, Inertial confinement fusion

Abstract

The south pole bang-time diagnostic views National Ignition Facility (NIF) implosions through the lower Hohlraum laser entrance hole to measure the time of peak x-ray emission (peak compression) in indirect-drive implosions. Five chemical-vapor-deposition diamond photoconductive detectors with different filtrations and sensitivities record the time-varying x rays emitted by the target. Wavelength selecting highly oriented pyrolytic graphite crystal mirror monochromators increase the x-ray signal-to-background ratio by filtering for 11-keV emission. Diagnostic timing and the in situ temporal instrument response function are determined from laser impulse shots on the NIF. After signal deconvolution and background removal, the bang time is determined to 45-ps accuracy. The x-ray “yield” (mJ/sr/keV at 11 keV) is determined from the time integral of the corrected peak signal.

Published

2012

28. Measuring x-ray burn history with the Streaked Polar Instrumentation for Diagnosing Energetic Radiation (SPIDER) at the National Ignition Facility (NIF)

Author

Randy T. Shelton, N. Izumi, D. K. Bradley, R. B. Petre, Daniel Headley, J. R. Kimbrough, Scott Burns, John R. Celeste, J. W. Kellogg, Andrew MacPhee, Lucile S. Dauffy, J. P. Holder, M. A. Gerhard, M. C. Jones, Y. P. Opachich, T. Thomas, John L. Porter, Perry M. Bell, C. A. Hagmann, J. B. Worden, Mark Eckart, Shahab Khan, N. E. Palmer, and Hesham Khater

Subjects

Physics, Streak camera, business.industry, Instrumentation, Implosion, law.invention, Ignition system, Optics, law, Temporal resolution, Neutron, National Ignition Facility, business, Image resolution

Abstract

We present a new diagnostic for the National Ignition Facility (NIF) [1,2]. The Streaked Polar Instrumentation for Diagnosing Energetic Radiation (SPIDER) is an x-ray streak camera for use on almost-igniting targets, up to ~10 17 neutrons per shot. It measures the x-ray burn history for ignition campaigns with the following requirements: X-Ray Energy 8-30keV, Temporal Resolution 10ps, Absolute Timing Resolution 30ps, Neutron Yield: 10 14 to 10 17 . The features of the design are a heavily shielded instrument enclosure outside the target chamber, remote location of the neutron and EMP sensitive components, a precise laser pulse comb fiducial timing system and fast streaking electronics. SPIDER has been characterized for sweep linearity, dynamic range, temporal and spatial resolution. Preliminary DT implosion data shows the functionality of the instrument and provides an illustration of the method of burn history extraction.

Published

2012

29. Neutron time-of-flight measurements on the national ignition facility

Author

T. C. Sangster, J. P. Knauer, James McNaney, E. J. Bond, J. D. Kilkenny, Christian Stoeckl, Mark Eckart, V. Yu. Glebov, Robert Hatarik, Michael J. Moran, D. D. Meyerhofer, Stephan Friedrich, J. A. Caggiano, and S. J. Padalino

Subjects

Physics, Photomultiplier, Time of flight, Physics::Instrumentation and Detectors, Nuclear engineering, Detector, Figure of merit, Neutron detection, Neutron, Scintillator, National Ignition Facility

Abstract

Neutron time-of-flight (nToF) instruments are used to provide data on the performance of National Ignition Facility (NIF) fusion experiments. Detectors are located at 4.5 and 20 meters from the center of the target chamber with a 3.9 meter detector to be installed soon. These instruments are used to measure the total neutron emission, temperature of the fuel, time of peak emission (bang time), and areal density of the compressed fuel ρr). This talk will focus on data from the 20 meter detectors which are Xylene based liquid scintillators coupled to micro-channel plate photomultipliers. A figure of merit defined by the ratio of number of neutrons from 10 to 12 MeV divided by the number of neutrons between 13 and 15 MeV, called the down-scatter-ratio (DSR), is used to infer ρr. Analysis techniques using both time domain and energy domain data are discussed showing limitations and error analysis of both methods. Simulated data for an improved detector based on an organic crystal scintillator show that improvements to both scintillator decay and recording fidelity improve the precision of the DSR measurement

Published

2011

30. Publisher’s Note: Demonstration of Ignition Radiation Temperatures in Indirect-Drive Inertial Confinement Fusion Hohlraums [Phys. Rev. Lett.106, 085004 (2011)]

Author

B. L. Pepmeier, D. L. Hodtwalker, B. V. Beeman, J. D. Hollis, P. S. Yang, S. A. Silva, M. J. Richardson, J. L. Vaher, K. Gu, B. N. M. Balaoing, J. E. Krammen, P. J. van Arsdall, N. I. Spafford, M. M. Montoya, M. A. Jackson, F. W. Chambers, J. Grippen, M. Neto, P. H. Gschweng, J. D. Moody, C. A. Haynam, S. Huber, A. P. Ludwigsen, E T Alger, G. M. Curnow, J. Watkins, J. C. Ellefson, S. Sailors, B. McHale, L. F. Alvarez, H. Chandrasekaran, T. E. Mills, Cliff Thomas, P. L. Stratton, R. Zacharias, J. D. Hitchcock, P. M. Bell, J. F. Meeker, E. L. Dewald, R. K. Butlin, T. G. Stone, K. P. Youngblood, Mark W. Bowers, M. Runkel, E. Padilla, M. W. Owens, S. S. Alvarez, J. G. Soto, L. J. Atherton, J. McBride, W. A. Reid, M. Y. Mauvais, G. Heestand, O. D. Edwards, S. W. Lane, A. A. Marsh, T. N. Malsbury, S. R. Robison, P. M. Danforth, J. D. Kilkenny, J. A. Baltz, M. J. Dailey, R. C. Montesanti, J. D. Driscoll, B. J. MacGowan, M. K. Shiflett, Donald F. Browning, F. J. Lopez, C. R. Gibson, F. E. Wade, R. Darbee, Mark R. Hermann, B Fishler, Y. Chen, Edward I. Moses, G. A. Kyrala, R. D. Demaret, J. G. Lown, M. D. Magat, S. Azevedo, G. Erbert, R. K. Kirkwood, K. Charron, Harry B. Radousky, R. T. Shelton, M. E. Sheldrick, R. R. Lyons, C. T. Warren, Paul J. Wegner, P. V. Amick, B. Johnson, G. Hermes, K. M. Morriston, G. A. Keating, T. G. Parham, K. S. Andersson, G. Ross, C. H. Ellerbee, D. A. Callahan, A. S. Rivenes, C. B. Foxworthy, M. C. Johnson, R. Miramontes-Ortiz, P. T. Springer, P. Datte, T. Kohut, J. Neumann, A. J. van Prooyen, C. Thai, M. J. Edwards, K. Work, Tilo Döppner, K. D. Pletcher, G. Frieder, D. S. Hey, T. Ma, A. J. Churby, I. L. Maslennikov, M. C. Witte, Siegfried Glenzer, G. J. Mauger, B. E. Smith, Suhas Bhandarkar, S. C. Burkhart, Joseph Ralph, T. J. Clancy, E. Ng, Thomas J. Johnson, K. L. Griffin, Rolf K. Reed, J. Braucht, R. Rinnert, J.M.Fisher, J. M. Di Nicola, N. Lao, A. L. Throop, S. Hunter, R. L. Rampke, Nathan Meezan, D. A. Barker, Otto Landen, Mark Eckart, M. A. Bergonia, K. N. La Fortune, J. R. Kimbrough, T. R. Huppler, R. A. London, G. L. Tietbohl, J. J. Rhodes, Christoph Niemann, Richard Town, W. J. Fabyan, Joseph W. Carlson, K. M. Skulina, G. Pavel, T. W. Phillips, B. D. Cline, R. G. Hartley, R. J. Wallace, T. L. Lee, C. C. Widmayer, Steven H. Langer, L. F. Finnie, J. Morris, G. T. Villanueva, S. W. Kramer, L. K. Smith, J. W. Florio, D. Pigg, J. L. Vickers, A. S. Runtal, F. E. Coffield, D. G. Cocherell, Pamela K. Whitman, S. Le Pape, Michael Stadermann, E. A. Stout, J. Liebman, V. K. Lakamsani, D. K. Bradley, J. A. Borgman, D. G. Mathisen, M. D. Vergino, P. A. Arnold, Kenneth S. Jancaitis, M. D. Rosen, Jeremy Kroll, J. Dugorepec, M. F. Swisher, J. M. Tillman, D. Pendleton, D. E. Speck, E. Mertens, K. King, Q. M. Ngo, G. Bardsley, E. A. Tekle, R. Costa, Robert L. Kauffman, D. T. Boyle, J. E. Hamblen, D. M. Lord, B. L. Lechleiter, M.S.Hutton, T. Fung, J. R. Schaffer, E. M. Giraldez, S. N. Dixit, John R. Celeste, Laurent Divol, L. C. Clowdus, B. K. Young, D. Trummer, H. Gonzales, B. P. Golick, D. T. Maloy, J. P. Holder, Wendi Sweet, S. R. Marshall, G. J. Edwards, Sally Andrews, G. A. Deis, L. J. Bernardez, D. Larson, L. L. Silva, A. McGrew, G Brunton, S. M. Glenn, Alexander Thomas, Jay D. Salmonson, R. E. Olson, C. M. Estes, Wade H. Williams, K. G. Koka, A. I. Barnes, M. A. Vitalich, A. Y. Chakicherla, J. L. Reynolds, B. Haid, J. T. Salmon, L. V. Berzins, O. S. Jones, B. A. Wilson, M. G. Miller, L. M. Kegelmeyer, Mark J. Schmitt, E. J. Bond, D. R. Bopp, G. T. Lau, N. W. Lum, Kevin S. White, J. T. Fink, D. R. Hart, Marilyn Schneider, F. Stanley, D. B. Dobson, F. Barbosa, L. J. Suter, M. Shor, A. V. Hamza, D. L. Hardy, T. McCarville, D. L. Hipple, C. J. Roberts, P. W. Edwards, R. W. Patterson, Ronald B. Robinson, J. B. Tassano, B. S. Raimondi, S. R. Hahn, G. Gururangan, P. C. Dupuy, R. L. Hibbard, J. R. Nelson, D. A. Smauley, M. J. Fischer, J. H. Kamperschroer, G. Holtmeier, Andrew MacPhee, E. A. Williams, P. A. Adams, K. G. Krauter, Jose Milovich, Stephen P. Vernon, L. J. Lagin, G. N. Gawinski, J. S. Taylor, G. Antonini, M. P. Johnston, M. C. Valadez, M. A. Weingart, S. L. Edson, John Kline, S. M. Gross, A. Baron, J. D. Tappero, N. L. Orsi, J. A. Davis, J. Klingmann, N. J. Cahayag, Carlos E. Castro, J. D. Lindl, A. T. Rivera, L. R. Belk, S. L. Kenitzer, J. Duncan, K. E. Burns, A. L. Solomon, R. C. Bettenhausen, B. M. Van Wonterghem, S. P. Rogers, R G Beeler, D. Latray, H. K. Loey, T. M. Pannell, B. Felker, T. Frazier, V. Rekow, P. G. Zapata, A. J. Mackinnon, R. W. Carey, P. S. Cardinale, J. Jackson, John Moody, S. Burns, L. Willis, J. L. Bragg, D. E. Petersen, E. G. Dzenitis, D. R. Jedlovec, J. R. Cox, D. E. Hinkel, J. A. Robinson, John R. Bower, E. O. Vergel de Dios, B. A. Hammel, L. M. Burrows, Daniel H. Kalantar, Klaus Widmann, M. J. Christensen, R. Prasad, A. L. Warrick, K. Wilhelmsen, R. Chapman, O. R. Rodriguez, A. W. Huey, B. L. Olejniczak, G. W. Krauter, S. W. Haan, Claire Bishop, H. Zhang, J. B. Alfonso, J. H. Truong, S. Weaver, K. S. Segraves, S. Sommer, J. C. Bell, Y. Lee, S. Shiromizu, R. Saunders, R. N. Fallejo, K. Piston, J. Wen, R. M. Marquez, K. L. Tribbey, S. A. Gonzales, P. Di Nicola, R. M. Franks, A. Nikroo, G. A. Bowers, J. B. McCloud, K. A. Moreno, Nobuhiko Izumi, S. F. Locke, S. A. Vonhof, E. F. Wilson, M. D. Finney, D. P. Atkinson, Damien Hicks, R. Lowe-Webb, R. A. Sacks, B. Riordan, M. Fedorov, A. B. Langdon, Z. Alherz, D. N. Hulsey, E. K. Krieger, S. J. Cohen, T. M. Schindler, B. Burr, J. S. Merill, C. Powell, Pierre Michel, J. S. Zielinski, M. J. Gonzales, C. Marshall, Richard Berger, C. Chan, J. Li, S. L. Townsend, L. Auyang, F. A. Penko, A. D. Casey, C. Chang, D. L. Brinkerhoff, K. M. Knittel, R. J. Strauser, G. Markham, and M. J. Shaw

Subjects

Nuclear physics, Physics, Ignition system, Hohlraum, law, General Physics and Astronomy, Plasma confinement, Magnetic confinement fusion, Plasma, Atomic physics, Radiation, Inertial confinement fusion, law.invention

Published

2011

31. Demonstration of Ignition Radiation Temperatures in Indirect-Drive Inertial Confinement Fusion Hohlraums

Author

L. V. Berzins, L. M. Kegelmeyer, D. R. Hart, L. J. Suter, M. Shor, Ronald B. Robinson, S. S. Alvarez, G. Gururangan, Robert L. Kauffman, C. T. Warren, R. Darbee, Andrew MacPhee, J. R. Nelson, D. A. Smauley, M. J. Fischer, K. S. Andersson, D. A. Callahan, L. J. Atherton, D. S. Hey, J. D. Kilkenny, T. Ma, J. H. Kamperschroer, T. Frazier, T. J. Clancy, E. A. Williams, P. A. Adams, C. Thai, Laurent Divol, G. J. Edwards, Suhas Bhandarkar, K. Work, M. D. Magat, S. Hunter, Stephen P. Vernon, T. L. Lee, Rolf K. Reed, J.M.Fisher, O. S. Jones, D. Trummer, G. N. Gawinski, G. Antonini, M. P. Johnston, A. J. Mackinnon, M. E. Sheldrick, T. R. Huppler, B. A. Wilson, J. P. Holder, P. L. Stratton, Yiping Chen, J. Jackson, S. Sailors, John Moody, Mark J. Schmitt, L. K. Smith, R. G. Hartley, E. J. Bond, P. Datte, S. Burns, B. McHale, G. Bardsley, D. T. Boyle, D. R. Bopp, E. L. Dewald, J. E. Hamblen, L. Willis, K. G. Krauter, J. R. Schaffer, D. G. Mathisen, M. D. Rosen, J. Morris, M.S.Hutton, G. T. Lau, N. W. Lum, G. Hermes, G. A. Deis, K. N. La Fortune, M. C. Johnson, J. Neumann, C. C. Widmayer, Steven H. Langer, L. F. Finnie, M. C. Witte, K. King, Michael Stadermann, E. A. Stout, M. G. Miller, Wendi Sweet, T. G. Stone, E. A. Tekle, P. M. Danforth, H. Chandrasekaran, D. Larson, M. F. Swisher, J. T. Fink, G. Frieder, L. Bezerides, Kenneth S. Jancaitis, A. L. Throop, B. L. Lechleiter, S. N. Dixit, Kevin S. White, C. Chang, M. K. Shiflett, G. A. Kyrala, F. Stanley, J. Braucht, John Kline, S. M. Gross, A. Baron, R G Beeler, S. Azevedo, R. A. London, T. E. Mills, G Brunton, Marilyn Schneider, M. J. Dailey, R. C. Montesanti, J. Dugorepec, A. J. Churby, I. L. Maslennikov, D. Latray, F. Barbosa, P. A. Arnold, A. A. Marsh, J. J. Rhodes, G. L. Tietbohl, Alexander Thomas, D. B. Dobson, J. M. Tillman, L. L. Silva, G. Erbert, D. A. Barker, R. D. Demaret, J. A. Davis, S. M. Glenn, J. Klingmann, Edward I. Moses, T. M. Pannell, R. T. Shelton, J. M. Di Nicola, N. J. Cahayag, T. Fung, R. L. Rampke, S. Le Pape, Jay D. Salmonson, G. Ross, R. E. Olson, E. Mertens, J. D. Lindl, J. G. Lown, C. M. Estes, A. T. Rivera, Mark W. Bowers, M. Runkel, F. E. Coffield, Wade H. Williams, K. G. Koka, B. A. Hammel, L. M. Burrows, A. S. Rivenes, Daniel H. Kalantar, M. A. Vitalich, M. Y. Mauvais, D. G. Cocherell, J. Grippen, P. V. Amick, B. K. Young, J. G. Soto, A. McGrew, M. J. Edwards, Tilo Döppner, M. J. Christensen, Jeremy Kroll, J. L. Vaher, C. H. Ellerbee, T. N. Malsbury, C. A. Haynam, B. Haid, J. T. Salmon, A. J. van Prooyen, A. L. Warrick, R. Costa, A. V. Hamza, T. G. Parham, C. R. Gibson, S. A. Silva, D. Pendlton, A. W. Huey, P. M. Bell, K. P. Youngblood, B. N. M. Balaoing, Joseph Ralph, R. Rinnert, B Fishler, D. L. Hardy, K. D. Pletcher, J. Liebman, R. K. Butlin, B. Johnson, T. McCarville, L. C. Clowdus, Otto Landen, V. K. Lakamsani, B. P. Golick, F. W. Chambers, D. T. Maloy, D. L. Hipple, C. B. Foxworthy, O. D. Edwards, C. J. Roberts, T. Zaleski, S. C. Burkhart, Thomas J. Johnson, N. Lao, S. R. Marshall, J. A. Baltz, D. E. Speck, R. Miramontes, J. E. Krammen, P. J. van Arsdall, M. A. Bergonia, K. M. Skulina, R. J. Strausser, K. M. Knittel, Siegfried Glenzer, G. J. Mauger, B. E. Smith, Sally Andrews, G. Heestand, P. W. Edwards, E. M. Giraldez, John R. Celeste, N. I. Spafford, R. W. Patterson, J. Watkins, J. B. Tassano, J. C. Ellefson, B. S. Raimondi, Christoph Niemann, M. M. Montoya, M. A. Jackson, T. W. Phillips, H. Gonzales, E. Ng, Mark Eckart, D. M. Lord, S. R. Hahn, L. J. Bernardez, B. D. Cline, A. Forsman, J. W. Florio, D. Pigg, Donald F. Browning, J. L. Vickers, K. M. Morriston, G. A. Keating, G. Pavel, P. C. Dupuy, A. S. Runtal, R. L. Hibbard, P. T. Springer, T. Kohut, B. L. Pepmeier, Richard Town, W. J. Fabyan, S. Huber, A. P. Ludwigsen, G. Holtmeier, D. L. Hodtwalker, M. Neto, P. H. Gschweng, J. D. Moody, K. L. Griffin, B. V. Beeman, J. D. Hollis, E T Alger, G. M. Curnow, P. S. Yang, E. Padilla, M. W. Owens, M. J. Richardson, S. R. Robison, K. Gu, F. J. Lopez, G. Markham, M. J. Shaw, F. E. Wade, R. K. Kirkwood, Pamela K. Whitman, Cliff Thomas, L. F. Alvarez, D. K. Bradley, J. F. Meeker, J. A. Borgman, M. D. Vergino, J. McBride, W. A. Reid, D. E. Petersen, J. S. Taylor, G. T. Villanueva, M. C. Valadez, D. E. Hinkel, M. A. Weingart, K. Charron, S. W. Kramer, R. R. Lyons, S. L. Edson, Klaus Widmann, Q. M. Ngo, H. Zhang, J. B. Alfonso, S. Weaver, J. D. Driscoll, R. M. Marquez, R. M. Franks, A. Nikroo, Mark R. Hermann, R. A. Sacks, Harry B. Radousky, A. B. Langdon, Paul J. Wegner, E. K. Krieger, Pierre Michel, Richard Berger, C. Chan, J. Li, Jose Milovich, J. S. Merill, C. Powell, J. S. Zielinski, L. J. Lagin, S. P. Rogers, J. D. Tappero, N. L. Orsi, S. L. Townsend, L. Auyang, F. A. Penko, V. Rekow, P. G. Zapata, Carlos E. Castro, R. W. Carey, A. D. Casey, K. S. Segraves, D. R. Jedlovec, J. R. Cox, S. Sommer, J. C. Bell, D. L. Brinkerhoff, E. O. Vergel de Dios, G. A. Bowers, R. Zacharias, J. D. Hitchcock, S. W. Lane, R. Prasad, K. A. Moreno, B. J. MacGowan, K. Wilhelmsen, Nobuhiko Izumi, S. F. Locke, R. Chapman, O. R. Rodriguez, S. A. Vonhof, E. F. Wilson, B. L. Olejniczak, G. W. Krauter, R. Lowe-Webb, Nathan Meezan, J. R. Kimbrough, Claire Bishop, D. N. Hulsey, Joseph W. Carlson, R. N. Fallejo, M. J. Gonzalez, L. R. Belk, R. J. Wallace, S. L. Kenitzer, J. Duncan, K. Piston, J. Wen, K. E. Burns, K. L. Tribbey, S. A. Gonzales, J. H. Truong, P. Di Nicola, J. B. McCloud, Y. Lee, S. Shiromizu, T. M. Schindler, B. Burr, R. Saunders, C. Marshall, A. L. Solomon, R. C. Bettenhausen, B. M. Van Wonterghem, H. K. Loey, B. Felker, P. S. Cardinale, M. D. Finney, D. P. Atkinson, Damien Hicks, J. L. Bragg, E. G. Dzenitis, J. A. Robinson, John R. Bower, B. Riordan, S. W. Haan, M. Fedorov, Z. Alherz, S. J. Cohen, A. I. Barnes, A. Y. Chakicherla, and J. L. Reynolds

Subjects

Physics, business.industry, Physics::Optics, General Physics and Astronomy, Implosion, Radiation, Laser, law.invention, Ignition system, Optics, Physics::Plasma Physics, Hohlraum, law, Laser power scaling, Atomic physics, National Ignition Facility, business, Inertial confinement fusion, Astrophysics::Galaxy Astrophysics

Abstract

We demonstrate the hohlraum radiation temperature and symmetry required for ignition-scale inertial confinement fusion capsule implosions. Cryogenic gas-filled hohlraums with 2.2 mm-diameter capsules are heated with unprecedented laser energies of 1.2 MJ delivered by 192 ultraviolet laser beams on the National Ignition Facility. Laser backscatter measurements show that these hohlraums absorb 87% to 91% of the incident laser power resulting in peak radiation temperatures of T(RAD)=300 eV and a symmetric implosion to a 100 μm diameter hot core.

Published

2011

32. Modeling of neutron induced backgrounds in x-ray framing cameras

Author

Mark Eckart, J. A. Koch, D. K. Bradley, P. M. Bell, Gary Stone, A. Conder, J. D. Moody, C. Hagmann, Hesham Khater, and N. Izumi

Subjects

Nuclear reaction, Physics, Framing (visual arts), Physics::Instrumentation and Detectors, business.industry, Inelastic scattering, Neutron temperature, Nuclear physics, Optics, Neutron, Charge-coupled device, Nuclear Experiment, business, Instrumentation, Inertial confinement fusion, Cherenkov radiation

Abstract

Fast neutrons from inertial confinement fusion implosions pose a severe background to conventional multichannel plate (MCP)-based x-ray framing cameras for deuterium-tritium yields >1013. Nuclear reactions of neutrons in photosensitive elements (charge coupled device or film) cause some of the image noise. In addition, inelastic neutron collisions in the detector and nearby components create a large gamma pulse. The background from the resulting secondary charged particles is twofold: (1) production of light through the Cherenkov effect in optical components and by excitation of the MCP phosphor and (2) direct excitation of the photosensitive elements. We give theoretical estimates of the various contributions to the overall noise and present mitigation strategies for operating in high yield environments.

Published

2010

33. The National Ignition Facility neutron time-of-flight system and its initial performance (invited)

Author

L. Disdier, Christian Stoeckl, A. Pruyne, R. J. Leeper, James McNaney, V. Yu. Glebov, J. P. Knauer, O. Landoas, Milton J. Shoup, Gordon A. Chandler, J. J. Haslam, R. Zacharias, D. H. Munro, Colin Horsfield, D. P. Warwas, Wolfgang Stoeffl, Michael J. Moran, T. Buczek, M. Yeoman, Mark Eckart, J. D. Kilkenny, T. Duffy, W. Theobald, M. Cruz, D. H. Schneider, M. Fox, Thomas E. Clancy, M. H. Romanofsky, Kenneth L. Marshall, T. C. Sangster, J.-L. Bourgade, and R. A. Lerche

Subjects

Physics, Nuclear physics, Time of flight, Deuterium, Physics::Plasma Physics, Neutron detection, Neutron, Nuclear Experiment, National Ignition Facility, Instrumentation, Inertial confinement fusion, Particle detector, Doppler broadening

Abstract

The National Ignition Facility (NIF) successfully completed its first inertial confinement fusion (ICF) campaign in 2009. A neutron time-of-flight (nTOF) system was part of the nuclear diagnostics used in this campaign. The nTOF technique has been used for decades on ICF facilities to infer the ion temperature of hot deuterium (D(2)) and deuterium-tritium (DT) plasmas based on the temporal Doppler broadening of the primary neutron peak. Once calibrated for absolute neutron sensitivity, the nTOF detectors can be used to measure the yield with high accuracy. The NIF nTOF system is designed to measure neutron yield and ion temperature over 11 orders of magnitude (from 10(8) to 10(19)), neutron bang time in DT implosions between 10(12) and 10(16), and to infer areal density for DT yields above 10(12). During the 2009 campaign, the three most sensitive neutron time-of-flight detectors were installed and used to measure the primary neutron yield and ion temperature from 25 high-convergence implosions using D(2) fuel. The OMEGA yield calibration of these detectors was successfully transferred to the NIF.

Published

2010

34. Experimental study of neutron induced background noise on gated x-ray framing cameras

Author

R. Tommasini, J. A. Koch, Otto Landen, N. Izumi, George A. Kyrala, D. S. Hey, D. K. Bradley, P. T. Springer, Wolfgang Stoeffl, Hans W. Herrmann, C. Sorce, Gary Stone, A. J. Mackinnon, C. A. Hagmann, P. M. Bell, R. Bahukutumbi, A. Conder, Mark Eckart, T. C. Sangster, S. M. Glenn, V. Y. Glebov, and Alan T. Teruya

Subjects

Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, X-ray, Laser, Diagnostic tools, law.invention, Background noise, Optics, law, Neutron, Plasma diagnostics, Microchannel plate detector, business, Instrumentation, Inertial confinement fusion

Abstract

A temporally gated x-ray framing camera based on a proximity focus microchannel plate is one of the most important diagnostic tools of inertial confinement fusion experiments. However, fusion neutrons produced in imploded capsules interact with structures surrounding the camera and produce background to x-ray signals. To understand the mechanisms of this neutron induced background, we tested several gated x-ray cameras in the presence of 14 MeV neutrons produced at the Omega laser facility. Differences between background levels observed with photographic film readout and charge-coupled-device readout have been studied.

Published

2010

35. Understanding the stagnation and burn of implosions on NIF

Author

Nathan Meezan, J. P. Knauer, C. J. Cerjan, V. Yu. Glebov, S. V. Weber, D. H. Munro, Mark Eckart, Brian Spears, Daniel Sayre, J. D. Kilkenny, A. J. Mackinnon, L. Berzak-Hopkins, O. S. Jones, Laurent Divol, Gary Grim, J. A. Frenje, James McNaney, C. B. Yeamans, Daniel Casey, Maria Gatu-Johnson, R. D. Petrasso, Wolfgang Stoeffl, Hans Rinderknecht, Hans W. Herrmann, Robert Hatarik, S. Le Pape, J. A. Caggiano, and Alex Zylstra

Subjects

010302 applied physics, History, Materials science, Drift velocity, Plasma, 01 natural sciences, 010305 fluids & plasmas, Computer Science Applications, Education, Computational physics, Core (optical fiber), Nuclear magnetic resonance, 0103 physical sciences, Area density, Anisotropy

Abstract

An improved the set of nuclear diagnostics on NIF measures the properties of the stagnation plasma of implosions, including the drift velocity, areal density (ρr) anisotropy and carbon ρr of the compressed core. Two types of deuterium-tritium (DT) gas filled targets are imploded by shaped x-ray pulses, producing stagnated and burning DT cores of radial convergence (Cr) ~ 5 or ~20. Comparison with two-dimensional modeling with inner and outer surface mix shows good agreement with nuclear measurements.

Published

2016

36. Analysis of the neutron time-of-flight spectra from inertial confinement fusion experiments

Author

Gary Grim, Robert Hatarik, D. H. Munro, James McNaney, Thomas G. Phillips, E. P. Hartouni, Daniel Sayre, E. J. Bond, C. J. Cerjan, J. A. Caggiano, J. P. Knauer, and Mark Eckart

Subjects

Physics, Nuclear physics, Time of flight, Scattering, Yield (chemistry), Helium-3, General Physics and Astronomy, Plasma diagnostics, Neutron, Inertial confinement fusion, Spectral line

Abstract

Neutron time-of-flight diagnostics have long been used to characterize the neutron spectrum produced by inertial confinement fusion experiments. The primary diagnostic goals are to extract the d + t → n + α (DT) and d + d → n + 3He (DD) neutron yields and peak widths, and the amount DT scattering relative to its unscattered yield, also known as the down-scatter ratio (DSR). These quantities are used to infer yield weighted plasma conditions, such as ion temperature (Tion) and cold fuel areal density. We report on novel methodologies used to determine neutron yield, apparent Tion, and DSR. These methods invoke a single temperature, static fluid model to describe the neutron peaks from DD and DT reactions and a spline description of the DT spectrum to determine the DSR. Both measurements are performed using a forward modeling technique that includes corrections for line-of-sight attenuation and impulse response of the detection system. These methods produce typical uncertainties for DT Tion of 250 eV, 7% fo...

Published

2015

37. Cryogenic tritium-hydrogen-deuterium and deuterium-tritium layer implosions with high density carbon ablators in near-vacuum hohlraums

Author

B. E. Yoxall, W. W. Hsing, Joseph Ralph, E. P. Hartouni, Juergen Biener, S. W. Haan, Otto Landen, Robert Hatarik, S. Le Pape, Nathan Meezan, P. K. Patel, S. M. Sepke, George A. Kyrala, A. V. Hamza, D. K. Bradley, Michael Stadermann, Daniel Sayre, Jeremy Kroll, James Ross, Jose Milovich, Cliff Thomas, C. Wild, J. D. Kilkenny, J. R. Rygg, Arthur Pak, Darwin Ho, N. Izumi, Mark Eckart, Laura Robin Benedetti, Laurent Divol, Richard Town, Brian Spears, Shahab Khan, Abbas Nikroo, R. Bionta, L. F. Berzak Hopkins, D. Hoover, M. Gatu Johnson, A. J. Mackinnon, John Moody, Daniel S. Clark, M. J. Edwards, Tilo Döppner, Gary Grim, R. Tommasini, B. J. Kozioziemski, J. E. Field, O. S. Jones, Peter M. Celliers, E. J. Bond, Tammy Ma, James McNaney, and J. A. Caggiano

Subjects

Physics, Laser ablation, Streak camera, business.industry, Implosion, Condensed Matter Physics, Laser, law.invention, Ignition system, Optics, law, Hohlraum, Atomic physics, National Ignition Facility, business, Inertial confinement fusion

Abstract

High Density Carbon (or diamond) is a promising ablator material for use in near-vacuum hohlraums, as its high density allows for ignition designs with laser pulse durations of

Published

2015

38. Simulations of indirectly driven gas-filled capsules at the National Ignition Facility

Author

D. H. Munro, Andrew MacPhee, Gary Grim, M. Mintz, Mark Eckart, C. J. Cerjan, M. J. Edwards, D. Rowley, A. V. Hamza, Richard Town, Johan Frenje, Nathan Meezan, Daniel S. Clark, Debra Callahan, Doug Wilson, A. L. Kritcher, L. F. Berzak Hopkins, V. A. Smalyuk, John Kline, S. V. Weber, S. Le Pape, J. Pino, D. Hoover, V. Y. Glebov, Tammy Ma, C. B. Yeamans, D. H. Edgell, Shabbir A. Khan, A. J. Mackinnon, J. A. Caggiano, Bruce Remington, A. S. Moore, Alex Zylstra, Brian Spears, David N. Fittinghoff, D. K. Bradley, Hans W. Herrmann, Hans Rinderknecht, S. M. Glenn, D. L. Bleuel, O. S. Jones, Abbas Nikroo, Otto Landen, James McNaney, T. G. Parham, R. Benedetti, N. Guler, W. W. Hsing, Frank E. Merrill, Petr Volegov, Maria Gatu-Johnson, Daniel Casey, E. J. Bond, Daniel Sayre, M. L. Kervin, N. Izumi, R. D. Petrasso, Laurent Divol, S. W. Haan, Robert Tipton, M. A. Barrios, J. P. Knauer, R. Tommasini, Arthur Pak, S. M. Sepke, George A. Kyrala, D. C. Eder, Wolfgang Stoeffl, Klaus Widmann, M. M. Marinak, J. D. Kilkenny, and Robert Hatarik

Subjects

Physics, Tritium illumination, Nuclear engineering, Cryogenics, Surface finish, Condensed Matter Physics, law.invention, Physics::Fluid Dynamics, Condensed Matter::Soft Condensed Matter, Ignition system, Fuel gas, Physics::Plasma Physics, law, Neutron, Atomic physics, National Ignition Facility, Inertial confinement fusion, Astrophysics::Galaxy Astrophysics

Abstract

Gas-filled capsules imploded with indirect drive on the National Ignition Facility have been employed as symmetry surrogates for cryogenic-layered ignition capsules and to explore interfacial mix. Plastic capsules containing deuterated layers and filled with tritium gas provide a direct measure of mix of ablator into the gas fuel. Other plastic capsules have employed DT or D3He gas fill. We present the results of two-dimensional simulations of gas-filled capsule implosions with known degradation sources represented as in modeling of inertial confinement fusion ignition designs; these are time-dependent drive asymmetry, the capsule support tent, roughness at material interfaces, and prescribed gas-ablator interface mix. Unlike the case of cryogenic-layered implosions, many observables of gas-filled implosions are in reasonable agreement with predictions of these simulations. Yields of TT and DT neutrons as well as other x-ray and nuclear diagnostics are matched for CD-layered implosions. Yields of DT-filled capsules are over-predicted by factors of 1.4–2, while D3He capsule yields are matched, as well as other metrics for both capsule types.

Published

2014

39. Nuclear imaging of the fuel assembly in ignition experiments

Author

L. A. Bernstein, D. T. Casey, D. G. Mathisen, B. M. Van Wonterghem, Christopher Danly, J. M. Di Nicola, G. Erbert, W. W. Hsing, D. H. Edgell, Frank E. Merrill, H. G. Rinderknecht, S. N. Dixit, S. M. Glenn, Pamela K. Whitman, Jay D. Salmonson, R. E. Olson, E. L. Dewald, Robert L. Kauffman, J. P. Knauer, Mahalia Jackson, John Kline, Mark Eckart, Laura Robin Benedetti, R. Zacharias, D. H. Munro, Mark W. Bowers, M. A. Barrios, Owen B. Drury, J. R. Cradick, Carlos E. Castro, B. R. Nathan, Denise Hinkel, L. V. Berzins, L. J. Atherton, J. A. Koch, Cliff Thomas, Michael J. Moran, Edward I. Moses, T. L. Lewis, J. D. Kilkenny, Richard Town, R. Saunders, S. V. Weber, C. Choate, David N. Fittinghoff, Carl Wilde, Rachna Prasad, L. J. Suter, R. J. Fortner, James McNaney, Petr Volegov, R. J. Leeper, A. S. Moore, Arthur Pak, D. L. Bleuel, B. J. MacGowan, J. R. Cox, G. LaCaille, D. K. Bradley, E. G. Dzenitis, P. Datte, Laurent Divol, T. G. Parham, Pierre Michel, Richard Berger, P. W. McKenty, Marilyn Schneider, Chimpén Ruiz, Otto Landen, N. Simanovskaia, G. W. Cooper, G. Gururangan, D. H. Schneider, Hans W. Herrmann, G. Frieders, Gary Grim, J. A. Frenje, T. R. Boehly, K. N. La Fortune, A. L. Kritcher, K. D. Hahn, George A. Kyrala, Evan Mapoles, D. C. Eder, B. A. Hammel, Daniel H. Kalantar, P. K. Patel, J. E. Ralph, David R. Farley, Charles D. Orth, D. Larson, D. M. Holunga, Gordon A. Chandler, T. C. Sangster, J. P. Holder, E. P. Hartouni, S. W. Haan, C. J. Cerjan, G. L. Morgan, Tammy Ma, M. J. Shaw, R. A. Buckles, G Brunton, Gilbert Collins, Jeremy Kroll, Brian Felker, G. W. Krauter, Mark R. Hermann, R. C. Ashabranner, Suhas Bhandarkar, C. R. Gibson, Jon Eggert, N. Izumi, P. A. Arnold, S. P. Hatchett, Jose Milovich, Rebecca Dylla-Spears, Wolfgang Stoeffl, Paul J. Wegner, R. D. Petrasso, K. A. Moreno, A. J. Traille, C. Marshall, R. M. Bionta, R. Tommasini, Kumar Raman, J. D. Lindl, M. I. Kauffman, L. J. Lagin, S. C. Burkhart, Christian Stoeckl, Klaus Widmann, Stephan Friedrich, R. Lowe-Webb, Riccardo Betti, G. Ross, J. A. Caggiano, S. Weaver, Alex Zylstra, Susan Regan, E. M. Giraldez, S. H. Glenzer, C. C. Widmayer, Melissa Edwards, A. Nikroo, Nathan Meezan, J. R. Kimbrough, Doug Wilson, R. M. Malone, K. M. Knittel, Robert Hatarik, D. Latray, T. Kohut, O. S. Jones, Peter M. Celliers, A. J. Mackinnon, B. J. Kozioziemski, E T Alger, R. W. Patterson, E. J. Bond, Steven H. Batha, S. J. Cohen, R. B. Ehrlich, Andrew MacPhee, T. A. Land, R. F. Burr, F. H. Séguin, B. K. Young, Sebastien LePape, K. G. Krauter, R. D. Wood, N. Guler, Brian Spears, Shahab Khan, J. D. Moody, R. K. Kirkwood, Daniel Clark, A. J. Nelson, J. D. Sater, J. Fair, V. Y. Glebov, T. N. Malsbury, J. B. Horner, H. Huang, Harry Robey, E. S. Palma, Kenneth S. Jancaitis, Maria Gatu-Johnson, Debra Callahan, C. A. Haynam, P. M. Bell, R. J. Wallace, P. T. Springer, Damien Hicks, P. Di Nicola, and A. V. Hamza

Subjects

Physics, Nuclear engineering, Condensed Matter Physics, law.invention, Ignition system, Nuclear physics, Physics::Plasma Physics, law, Hotspot (geology), Nuclear fusion, Plasma diagnostics, Neutron, Area density, Stagnation pressure, Inertial confinement fusion

Abstract

First results from the analysis of neutron image data collected on implosions of cryogenically layered deuterium-tritium capsules during the 2011-2012 National Ignition Campaign are reported. The data span a variety of experimental designs aimed at increasing the stagnation pressure of the central hotspot and areal density of the surrounding fuel assembly. Images of neutrons produced by deuterium–tritium fusion reactions in the hotspot are presented, as well as images of neutrons that scatter in the surrounding dense fuel assembly. The image data are compared with 1D and 2D model predictions, and consistency checked using other diagnostic data. The results indicate that the size of the fusing hotspot is consistent with the model predictions, as well as other imaging data, while the overall size of the fuel assembly, inferred from the scattered neutron images, is systematically smaller than models' prediction. Preliminary studies indicate these differences are consistent with a significant fraction (20%–25%) of the initial deuterium-tritium fuel mass outside the compact fuel assembly, due either to low mode mass asymmetry or high mode 3D mix effects at the ablator-ice interface.

Published

2013

40. Diagnosing implosion performance at the National Ignition Facility (NIF) by means of neutron spectrometry

Author

S. M. Sepke, V. Yu. Glebov, R. J. Leeper, J. D. Kilkenny, P. T. Springer, R. Bionta, James McNaney, Christian Stoeckl, Johan Frenje, R. A. Lerche, J. P. Knauer, Mark Eckart, R. D. Petrasso, Doug Wilson, Gary Grim, Otto Landen, Fredrick Seguin, S. Le Pape, Frank E. Merrill, D. T. Casey, O. S. Jones, David N. Fittinghoff, S. H. Glenzer, J. A. Caggiano, J. Edwards, E. J. Bond, Thomas J. Murphy, C. K. Li, Robert Hatarik, S. W. Haan, Stephan Friedrich, Ryan Rygg, M. Gatu Johnson, A. J. Mackinnon, Brian Spears, T. C. Sangster, S. P. Hatchett, D. H. Munro, Michael J. Moran, and C. J. Cerjan

Subjects

Physics, Nuclear and High Energy Physics, Spectrometer, Implosion, Condensed Matter Physics, Kinetic energy, law.invention, Nuclear physics, Ignition system, Recoil, Deuterium, Physics::Plasma Physics, law, Neutron, National Ignition Facility

Abstract

The neutron spectrum from a cryogenically layered deuterium?tritium (dt) implosion at the National Ignition Facility (NIF) provides essential information about the implosion performance. From the measured primary-neutron spectrum (13?15?MeV), yield (Yn) and hot-spot ion temperature (Ti) are determined. From the scattered neutron yield (10?12?MeV) relative to Yn, the down-scatter ratio, and the fuel areal density (?R) are determined. These implosion parameters have been diagnosed to an unprecedented accuracy with a suite of neutron-time-of-flight spectrometers and a magnetic recoil spectrometer implemented in various locations around the NIF target chamber. This provides good implosion coverage and excellent measurement complementarity required for reliable measurements of Yn, Ti and ?R, in addition to ?R asymmetries. The data indicate that the implosion performance, characterized by the experimental ignition threshold factor, has improved almost two orders of magnitude since the first shot taken in September 2010. ?R values greater than 1?g?cm?2 are readily achieved. Three-dimensional semi-analytical modelling and numerical simulations of the neutron-spectrometry data, as well as other data for the hot spot and main fuel, indicate that a maximum hot-spot pressure of ?150?Gbar has been obtained, which is almost a factor of two from the conditions required for ignition according to simulations. Observed Yn are also 3?10 times lower than predicted. The conjecture is that the observed pressure and Yn deficits are partly explained by substantial low-mode ?R asymmetries, which may cause inefficient conversion of shell kinetic energy to hot-spot thermal energy at stagnation.

Published

2013

41. Absolute measurement of the DT primary neutron yield on the National Ignition Facility

Author

R. D. Petrasso, T. C. Sangster, Mark Eckart, J. P. Knauer, L.A. Linden-Levy, J. A. Frenje, Gary Wayne Cooper, R. J. Leeper, Chimpén Ruiz, M. Gatu Johnson, Gordon A. Chandler, E. P. Hartouni, C. A. Hagmann, S. Padalino, J. D. Kilkenny, D. L. Bleuel, K. M. Knittel, D. T. Casey, Fredrick Seguin, and V. Yu. Glebov

Subjects

Physics, Ignition system, Absolute measurement, Neutron yield, Physics::Plasma Physics, law, QC1-999, Nuclear engineering, Mechanical engineering, National Ignition Facility, Inertial confinement fusion, law.invention

Abstract

The measurement of the absolute neutron yield produced in inertial confinement fusion target experiments conducted on the National Ignition Facility (NIF) is essential in benchmarking progress towards the goal of achieving ignition on this facility. This paper describes three independent diagnostic techniques that have been developed to make accurate and precise DT neutron yield measurements on the NIF.

Published

2013

42. Deuterium–tritium neutron yield measurements with the 4.5 m neutron-time-of-flight detectors at NIF

Author

E. J. Bond, V. Yu. Glebov, Mark Eckart, T. J. Clancy, Michael J. Moran, and Hesham Khater

Subjects

Physics, Nuclear physics, Deuterium, Physics::Instrumentation and Detectors, Neutron detection, Neutron, Scintillator, Fusion power, National Ignition Facility, Instrumentation, Inertial confinement fusion, Particle detector

Abstract

The first several campaigns of laser fusion experiments at the National Ignition Facility (NIF) included a family of high-sensitivity scintillator∕photodetector neutron-time-of-flight (nTOF) detectors for measuring deuterium-deuterium (DD) and DT neutron yields. The detectors provided consistent neutron yield (Y(n)) measurements from below 10(9) (DD) to nearly 10(15) (DT). The detectors initially demonstrated detector-to-detector Y(n) precisions better than 5%, but lacked in situ absolute calibrations. Recent experiments at NIF now have provided in situ DT yield calibration data that establish the absolute sensitivity of the 4.5 m differential tissue harmonic imaging (DTHI) detector with an accuracy of ± 10% and precision of ± 1%. The 4.5 m nTOF calibration measurements also have helped to establish improved detector impulse response functions and data analysis methods, which have contributed to improving the accuracy of the Y(n) measurements. These advances have also helped to extend the usefulness of nTOF measurements of ion temperature and downscattered neutron ratio (neutron yield 10-12 MeV divided by yield 13-15 MeV) with other nTOF detectors.

Published

2012

43. National Ignition Facility neutron time-of-flight measurements (invited)

Author

J. J. Haslam, T. J. Clancy, Christian Stoeckl, T. C. Sangster, Mark Eckart, J. P. Knauer, R. Zacharias, R. A. Lerche, Colin Horsfield, D. P. Warwas, V. Yu. Glebov, Michael J. Moran, M. Yeoman, J. D. Kilkenny, and James McNaney

Subjects

Nuclear physics, Physics, Time of flight, Physics::Instrumentation and Detectors, Monte Carlo method, Neutron diffraction, Detector, Neutron, Plasma diagnostics, Neutron scattering, National Ignition Facility, Instrumentation

Abstract

The first 3 of 18 neutron time-of-flight (nTOF) channels have been installed at the National Ignition Facility (NIF). The role of these detectors includes yield, temperature, and bang time measurements. This article focuses on nTOF data analysis and quality of results obtained for the first set of experiments to use all 192 NIF beams. Targets produced up to 2×10(10) 2.45 MeV neutrons for initial testing of the nTOF detectors. Differences in neutron scattering at the OMEGA laser facility where the detectors were calibrated and at NIF result in different response functions at the two facilities. Monte Carlo modeling shows this difference. The nTOF performance on these early experiments indicates that the nTOF system with its full complement of detectors should perform well in future measurements of yield, temperature, and bang time.

Published

2010

44. Radiation hardening of gated x-ray imagers for the National Ignition Facility (invited)

Author

Perry M. Bell, John R. Celeste, A. Conder, J. D. Kilkenny, J. D. Moody, D. S. Hey, C. J. Cerjan, D. K. Bradley, C. A. Hagmann, Alan T. Teruya, Hesham Khater, J. Ayers, Mark Eckart, N. Izumi, and J. R. Kimbrough

Subjects

Physics, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Implosion, Plasma, Laser, Signal, law.invention, Optics, Physics::Plasma Physics, law, Neutron, Plasma diagnostics, business, National Ignition Facility, Instrumentation, Radiation hardening

Abstract

The National Ignition Facility will soon be producing x-ray flux and neutron yields higher than any produced in laser driven implosion experiments in the past. Even a non-igniting capsule will require x-ray imaging of near burning plasmas at 10(17) neutrons, requiring x-ray recording systems to work in more hostile conditions than we have encountered in past laser facilities. We will present modeling, experimental data and design concepts for x-ray imaging with electronic recording systems for this environment (ARIANE). A novel instrument, active readout in a nuclear environment, is described which uses the time-of-flight difference between the gated x-ray signal and the neutron which induces a background signal to increase the yield at which gated cameras can be used.

Published

2010

45. Assessment and mitigation of radiation, EMP, debris & shrapnel impacts at megajoule-class laser facilities

Author

A Throop, A Geille, Aaron Fisher, O. S. Jones, C. S. Debonnel, T. J. Clancy, C. G. Brown, Otto Landen, Andrew MacPhee, J. R. Kimbrough, P Song, R. Tommasini, Alice Koniges, Pamela K. Whitman, Daniel H. Kalantar, J. Raimbourg, Perry M. Bell, R W Anderson, Andrea L. Bertozzi, M L Stowell, Joseph Teran, W Bittle, Hesham Khater, N. Masters, Stanley Osher, J. P. Holder, V. Rekow, B. J. MacGowan, D. K. Bradley, C. Stoeckl, J. P. Jadaud, P. Combis, D S Bailey, Brian Maddox, David J. Benson, Mark Eckart, Vladimir Glebov, J. Vierne, H. Chen, D. C. Eder, C. Sangster, Marc A. Meyers, Lucile S. Dauffy, J.-M. Chevalier, R. Prasad, D. Raffestin, T B Kaiser, and Daniel A. White

Subjects

History, Materials science, business.industry, Nuclear engineering, Electrical engineering, Radiation, Laser, Debris, Computer Science Applications, Education, law.invention, law, Neutron, business, Electromagnetic pulse

Abstract

The generation of neutron/gamma radiation, electromagnetic pulses (EMP), debris and shrapnel at mega-Joule class laser facilities (NIF and LMJ) impacts experiments conducted at these facilities. The complex 3D numerical codes used to assess these impacts range from an established code that required minor modifications (MCNP - calculates neutron and gamma radiation levels in complex geometries), through a code that required significant modifications to treat new phenomena (EMSolve - calculates EMP from electrons escaping from laser targets), to a new code, ALE-AMR, that is being developed through a joint collaboration between LLNL, CEA, and UC (UCSD, UCLA, and LBL) for debris and shrapnel modelling.

Published

2010

46. Laser coupling to reduced-scale hohlraum targets at the Early Light Program of the National Ignition Facility

Author

John R. Murray, E. L. Dewald, G. Bonanno, Edward I. Moses, A.D. Ellis, M. Landon, L. James, L. J. Suter, J. Emig, Denise Hinkel, Franz A. Weber, H. A. Baldis, F. D. Lee, B. K. F. Young, G. Holtmeier, B. M. Van Wonterghem, Marilyn Schneider, D. H. Munro, Paul J. Wegner, Alice Koniges, B. J. MacGowan, D. C. Eder, Ronnie Shepherd, Dustin Froula, J. H. Kamperschroer, S. Compton, Charles H. Still, J. R. Kimbrough, S. H. Glenzer, A. J. Mackinnon, S. N. Dixit, E. A. Williams, Otto Landen, G. L. Tietbohl, V. Rekow, R. J. Wallace, C. Niemann, R. Costa, M. S. Singh, J.A. Ruppe, K. M. Campbell, D. Bower, Kenneth R. Manes, R. K. Kirkwood, Daniel H. Kalantar, A. L. Warrick, M.A. Henesian, P.E. Young, Mark Eckart, Robert L. Kauffman, J. P. Holder, John R. Celeste, D. Pellinen, Phillip W. Watts, A. B. Langdon, D. Hargrove, M. J. Edwards, R. E. Turner, Kenneth S. Jancaitis, Robert Heeter, P. T. Springer, C. A. Haynam, J. W. McDonald, Mark May, C. Marshall, Jochen Schein, and J. Menapace

Subjects

Physics, Backscatter, Forward scatter, business.industry, Condensed Matter Physics, Laser, Ray, Electromagnetic radiation, law.invention, symbols.namesake, Optics, Hohlraum, law, symbols, Rayleigh scattering, business, National Ignition Facility

Abstract

A platform for analysis of material properties under extreme conditions, where a sample is bathed in radiation with a high temperature, is under development. Depositing maximum laser energy into a small, high-Z enclosure produces this hot environment. Such targets were recently included in an experimental campaign using the first four of the 192 beams of the National Ignition Facility [J. A. Paisner, E. M. Campbell, and W. J. Hogan, Fusion Technol. 26, 755 (1994)], under construction at the University of California Lawrence Livermore National Laboratory. These targets demonstrate good laser coupling, reaching a radiation temperature of 340 eV. In addition, there is a unique wavelength dependence of the Raman backscattered light that is consistent with Brillouin backscatter of Raman forward scatter [A. B. Langdon and D. E. Hinkel, Phys. Rev. Lett. 89, 015003 (2002)]. Finally, novel diagnostic capabilities indicate that 20% of the direct backscatter from these reduced-scale targets is in the polarization orthogonal to that of the incident light.

Published

2005

47. Observation of soft x‐ray amplification in neonlike molybdenum

Author

J. Woodworth, Dennis L Matthews, B. J. MacGowan, R. S. Walling, James H. Scofield, Peter L. Hagelstein, M. D. Rosen, James E. Trebes, G. Shimkaveg, Mark Eckart, B. L. Whitten, D. G. Nilson, and T. W. Phillips

Subjects

Materials science, Gain, General Physics and Astronomy, chemistry.chemical_element, Plasma, Laser, law.invention, Neon, chemistry, Molybdenum, law, Irradiation, Atomic physics, FOIL method, Line (formation)

Abstract

Thin molybdenum coated foils have been irradiated in line focus geometry with from 3 to 8×1014 W cm−2 of 0.53‐μm light at the Nova laser. The resulting exploding foil plasma has demonstrated x‐ray laser gain at four wavelengths (106.4, 131.0, 132.7, and 139.4 A), identified as 3s‐3p transitions in neonlike Mo. The J=0–1, a 3s–3p transition at 141.6 A has been identified, but does not show evidence of significant gain in disagreement with the theory.

Published

1987

48. Lawrence Livermore National Laboratory X-Ray Laser Research: Recent Results

Author

R. A. London, Thomas G. Phillips, B. J. MacGowan, S. Brown, A. Simon, Mark Eckart, J. Woodworth, D. G. Nilson, E. M. Campbell, D. A. Whelan, G. Shimkaveg, M. D. Rosen, James H. Scofield, B. L. Whitten, Dennis L Matthews, James E. Trebes, Christopher J. Keane, Peter L. Hagelstein, and Richard E. Stewart

Subjects

Radiative cooling, Chemistry, business.industry, Amplifier, Plasma, Laser, law.invention, X-ray laser, Optics, law, Extreme ultraviolet, Picosecond, business, Inertial confinement fusion

Abstract

Since the successful demonstration of gain in neon-like selenium using an exploding foil amplifier, the x-ray laser group at Lawrence Livermore National Laboratory has investigated further the exploding foil amplifier concept for use in XUV lasers. Results are reported of the characteristics of selenium amplifiers up to 50 mm in length. Observation of at least 16 gain lengths for the 206 A line of selenium is reported. Output powers in excess of 1 MW have been measured in pulses of approximately 200 picoseconds. The effects of refraction on the performance of long amplifiers have been studied. The occurrence time of the x-ray laser output relative to the input heating pulse has been measured and found to be in disagreement with a recent model that suggests three-body recombination driven by rapid radiative cooling as the inversion process in the selenium plasma.

Published

1987

49. REVIEW OF LIVERMORE'S SOFT X-RAY LASER PROGRAM

Author

M. D. Rosen, Thomas G. Phillips, D. G. Nilson, Peter L. Hagelstein, J. Woodworth, Dennis L Matthews, A. U. Hazi, B. J. MacGowan, Richard E. Stewart, S. Brown, D. A. Whelan, R. A. London, James E. Trebes, G. Shimkaveg, James H. Scofield, Mark Eckart, S. Maxon, B. L. Whitten, and David C. Eder

Subjects

Physics, business.industry, Amplifier, General Engineering, Laser, Population inversion, Electromagnetic radiation, Charged particle, law.invention, Wavelength, Optics, law, Extreme ultraviolet, business, Lasing threshold

Abstract

We will describe our optical laser pumped XUV Laser Program. To date, we have concentrated our efforts on exploding foil amplifier designs using Ne- and Ni-like n = 3p to 3s and n = 4f,d to 4,dp inversion schemes, respectively. We will describe our latest modeling results as well as measurements which demonstrate output power near the 1 MW level at 206 and 209 A and lasing at wavelengths as short as 106 A.

Published

1986