Your search keyword '"Bradley, D. K."' showing total 11 results

1. Symmetric Inertial Confinement Fusion Implosions at Ultra-High Laser Energies

Author

Glenzer, S. H., MacGowan, B. J., Michel, P., Meezan, N. B., Suter, L. J., Dixit, S. N., Kline, J. L., Kyrala, G. A., Bradley, D. K., Callahan, D. A., Dewald, E. L., Divol, L., Dzenitis, E., Edwards, M. J., Hamza, A. V., Haynam, C. A., Hinkel, D. E., Kalantar, D. H., Kilkenny, J. D., Landen, O. L., Lindl, J. D., LePape, S., Moody, J. D., Nikroo, A., Parham, T., Schneider, M. B., Town, R. P. J., Wegner, P., Widmann, K., Whitman, P., Young, B. K. F., Van Wonterghem, B., Atherton, L. J., and Moses, E. I.

Published

2010

2. The size and structure of the laser entrance hole in gas-filled hohlraums at the National Ignition Facility.

Author

Schneider, M. B., MacLaren, S. A., Widmann, K., Meezan, N. B., Hammer, J. H., Yoxall, B. E., Bell, P. M., Benedetti, L. R., Bradley, D. K., Callahan, D. A., Dewald, E. L., Döppner, T., Eder, D. C., Edwards, M. J., Guymer, T. M., Hinkel, D. E., Hohenberger, M., Hsing, W. W., Kervin, M. L., and Kilkenny, J. D.

Subjects

LASER beams, PLASMA gases, RADIATION, HYDRODYNAMICS, ENERGY transfer

Abstract

At the National Ignition Facility, a thermal X-ray drive is created by laser energy from 192 beams heating the inside walls of a gold cylinder called a "hohlraum." The x-ray drive heats and implodes a fuel capsule. The laser beams enter the hohlraum via laser entrance holes (LEHs) at each end. The LEH radius decreases as heated plasma from the LEH material blows radially inward but this is largely balanced by hot plasma from the high-intensity region in the center of the LEH pushing radially outward. The x-ray drive on the capsule is deduced by measuring the time evolution and spectra of the x-radiation coming out of the LEH and correcting for geometry and for the radius of the LEH. Previously, the LEH radius was measured using time-integrated images in an x-ray band of 3-5 keV (outside the thermal x-ray region). For gas-filled hohlraums, the measurements showed that the LEH radius is larger than that predicted by the standard High Flux radiation-hydrodynamic model by about 10%. A new platform using a truncated hohlraum ("ViewFactor hohlraum") is described, which allows time-resolved measurements of the LEH radius at thermal x-ray energies from two views, from outside the hohlraum and from inside the hohlraum. These measurements show that the LEH radius closes during the low power part of the pulse but opens up again at peak power. The LEH radius at peak power is larger than that predicted by the models by about 15%-20% and does not change very much with time. In addition, time-resolved images in a >4 keV (non-thermal) x-ray band show a ring of hot, optically thin gold plasma just inside the optically thick LEH plasma. The structure of this plasma varies with time and with Cross Beam Energy Transfer. [ABSTRACT FROM AUTHOR]

Published

2015

3. Laser absorption, power transfer, and radiation symmetry during the first shock of inertial confinement fusion gas-filled hohlraum experiments.

Author

Pak, A., Dewald, E. L., Landen, O. L., Milovich, J., Strozzi, D. J., Hopkins, L. F. Berzak, Bradley, D. K., Divol, L., Ho, D. D., MacKinnon, A. J., Meezan, N. B., Michel, P., Moody, J. D., Moore, A. S., Schneider, M. B., Town, R. P. J., Hsing, W. W., and Edwards, M. J.

Subjects

INERTIAL confinement fusion, ABSORPTION, BISMUTH, LASER pulses, LASER beams, ENERGY transfer

Abstract

Temporally resolved measurements of the hohlraum radiation flux asymmetry incident onto a bismuth coated surrogate capsule have been made over the first two nanoseconds of ignition relevant laser pulses. Specifically, we study the P2 asymmetry of the incoming flux as a function of cone fraction, defined as the inner-to-total laser beam power ratio, for a variety of hohlraums with different scales and gas fills. This work was performed to understand the relevance of recent experiments, conducted in new reduced-scale neopentane gas filled hohlraums, to full scale helium filled ignition targets. Experimental measurements, matched by 3D view factor calculations, are used to infer differences in symmetry, relative beam absorption, and cross beam energy transfer (CBET), employing an analytic model. Despite differences in hohlraum dimensions and gas fill, as well as in laser beam pointing and power, we find that laser absorption, CBET, and the cone fraction, at which a symmetric flux is achieved, are similar to within 25% between experiments conducted in the reduced and full scale hohlraums. This work demonstrates a close surrogacy in the dynamics during the first shock between reduced-scale and full scale implosion experiments and is an important step in enabling the increased rate of study for physics associated with inertial confinement fusion. [ABSTRACT FROM AUTHOR]

Published

2015

4. X-ray area backlighter development at the National Ignition Facility (invited).

Author

Barrios, M. A., Regan, S. P., Fournier, K. B., Epstein, R., Smith, R., Lazicki, A., Rygg, R., Fratanduono, D. E., Eggert, J., Park, H.-S., Huntington, C., Bradley, D. K., Landen, O. L., and Collins, G. W.

Subjects

SPECTRAL imaging, LASER beams, THERMODYNAMICS research, IRRADIATION

Abstract

1D spectral imaging was used to characterize the K-shell emission of Z ≈ 30-35 and Z ≈ 40-42 laser-irradiated foils at the National Ignition Facility. Foils were driven with up to 60 kJ of 3ω light, reaching laser irradiances on target between 0.5 and 20 x 1015 W/cm². Laser-to-X-ray conversion efficiency (CE) into the Heα line (plus satellite emission) of 1.0%-1.5% and 0.15%-0.2% was measured for Z ≈ 30-32 and Z ≈ 40-42, respectively. Measured CE into Heα (plus satellite emission) of Br (Z = 35) compound foils (either KBr or RbBr) ranged between 0.16% and 0.29%. Measured spectra are compared with 1D non-local thermodynamic equilibrium atomic kinetic and radiation transport simulations, providing a fast and accurate predictive capability. [ABSTRACT FROM AUTHOR]

Published

2014

5. Multistep redirection by cross-beam power transfer of ultrahigh-power lasers in a plasma.

Author

Moody, J. D., Michel, P., Divol, L., Berger, R. L., Bond, E., Bradley, D. K., Callahan, D. A., Dewald, E. L., Dixit, S., Edwards, M. J., Glenn, S., Hamza, A., Haynam, C., Hinkel, D. E., Izumi, N., Jones, O., Kilkenny, J. D., Kirkwood, R. K., Kline, J. L., and Kruer, W. L.

Subjects

LASER plasmas, PLASMA gases, OPTICS, LASER beams

Abstract

Laser redirection by cross-beam power transfer in a plasma is an important example of a nonlinear optics process which uses laser-plasma instabilities to one's advantage. We have demonstrated this in a hohlraum plasma at the National Ignition Facility (NIF) at Lawrence Livermore National Laboratory. A four-wave mixing process causes laser power in multiple beams to change direction and add to the laser power of a selected beam. The process is controlled by setting the wavelength separation of the interacting laser beams. This technique provides a method to remotely re-point or combine high-powered laser beams without the need of local optical apparatus. [ABSTRACT FROM AUTHOR]

Published

2012

6. Symmetry tuning via controlled crossed-beam energy transfer on the National Ignition Facility.

Author

Michel, P., Glenzer, S. H., Divol, L., Bradley, D. K., Callahan, D., Dixit, S., Glenn, S., Hinkel, D., Kirkwood, R. K., Kline, J. L., Kruer, W. L., Kyrala, G. A., Le Pape, S., Meezan, N. B., Town, R., Widmann, K., Williams, E. A., MacGowan, B. J., Lindl, J., and Suter, L. J.

Subjects

ENERGY transfer, LASERS, PLASMA gases, LASER beams, BACKSCATTERING

Abstract

The Hohlraum energetics experimental campaign started in the summer of 2009 on the National Ignition Facility (NIF) [E. I. Moses et al., Phys. Plasmas 16, 041006 (2009)]. These experiments showed good coupling of the laser energy into the targets [N. Meezan et al., Phys. Plasmas 17, 056304 (2010)]. They have also demonstrated controlled crossed-beam energy transfer between laser beams as an efficient and robust tool to tune the implosion symmetry of ignition capsules, as predicted by earlier calculations [P. Michel et al., Phys. Rev. Lett. 102, 025004 (2009)]. A new linear model calculating crossed-beam energy transfer between cones of beams on the NIF has been developed. The model has been applied to the subscale Hohlraum targets shot during the National Ignition Campaign in 2009. A good agreement can be found between the calculations and the experiments when the impaired propagation of the laser beams due to backscatter is accounted for. [ABSTRACT FROM AUTHOR]

Published

2010

7. Measurements of preheat and shock melting in Be ablators during the first few nanoseconds of a National Ignition Facility ignition drive using the Omega laser.

Author

Bradley, D. K., Prisbrey, S. T., Page, R. H., Braun, D. G., Edwards, M. J., Hibbard, R., Moreno, K. A., Mauldin, M. P., and Nikroo, A.

Subjects

*ABLATIVE materials, *INDUSTRIAL lasers, *LASER beams, *MECHANICAL shock, SPARK ignition engine ignition

Abstract

A scaled Hohlraum platform was used to experimentally measure preheat in ablator materials during the first few nanoseconds of a radiation drive proposed for ignition experiments at the National Ignition Facility [J. A. Paisner et al., Laser Focus World 30, 75 (1994)]. The platform design approximates the radiation environment of the pole of the capsule by matching both the laser spot intensity and illuminated Hohlraum wall fraction in scaled halfraums driven by the OMEGA laser system [T. R. Boehly et al., Opt. Commun. 133, 495 (1997)]. Back surface motion measured via VISAR reflecting from the rear surface of the sample was used to measure sample motion prior to shock breakout. The experiments show that the first ∼20 μm of a Be ablator will be melted by radiation preheat, with subsequent material melted by the initial shock, in agreement with simulations. The experiments also show no evidence of anomalous heating of buried high-Z doped layers in the ablator. [ABSTRACT FROM AUTHOR]

Published

2009

8. Progress towards ignition on the National Ignition Facility.

Author

Edwards, M. J., Patel, P. K., Lindl, J. D., Atherton, L. J., Glenzer, S. H., Haan, S. W., Kilkenny, J. D., Landen, O. L., Moses, E. I., Nikroo, A., Petrasso, R., Sangster, T. C., Springer, P. T., Batha, S., Benedetti, R., Bernstein, L., Betti, R., Bleuel, D. L., Boehly, T. R., and Bradley, D. K.

Subjects

DEUTERIUM plasma, NATIONAL security, INFRASTRUCTURE (Economics), PARAMETER estimation, LASER beams, PLASMA density

Abstract

The National Ignition Facility (NIF) at Lawrence Livermore National Laboratory includes a precision laser system now capable of delivering 1.8 MJ at 500 TW of 0.35-μm light to a target. NIF has been operational since March 2009. A variety of experiments have been completed in support of NIF's mission areas: national security, fundamental science, and inertial fusion energy. NIF capabilities and infrastructure are in place to support its missions with nearly 60 X-ray, optical, and nuclear diagnostic systems. A primary goal of the National Ignition Campaign (NIC) on the NIF was to implode a low-Z capsule filled with ∼0.2 mg of deuterium-tritium (DT) fuel via laser indirect-drive inertial confinement fusion and demonstrate fusion ignition and propagating thermonuclear burn with a net energy gain of ∼5-10 (fusion yield/input laser energy). This requires assembling the DT fuel into a dense shell of ∼1000 g/cm3 with an areal density (ρR) of ∼1.5 g/cm2, surrounding a lower density hot spot with a temperature of ∼10 keV and a ρR ∼0.3 g/cm2, or approximately an α-particle range. Achieving these conditions demand precise control of laser and target parameters to allow a low adiabat, high convergence implosion with low ablator fuel mix. We have demonstrated implosion and compressed fuel conditions at ∼80-90% for most point design values independently, but not at the same time. The nuclear yield is a factor of ∼3-10× below the simulated values and a similar factor below the alpha dominated regime. This paper will discuss the experimental trends, the possible causes of the degraded performance (the off-set from the simulations), and the plan to understand and resolve the underlying physics issues. [ABSTRACT FROM AUTHOR]

Published

2013

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

Author

Edgell, D. H., Bradley, D. K., Bond, E. J., Burns, S., Callahan, D. A, Celeste, J., Eckart, M. J., Glebov, V. Yu., Hey, D. S., Lacaille, G., Kilkenny, J. D., Kimbrough, J., Mackinnon, A. J., Magoon, J., Parker, J., Sangster, T. C., Shoup, M. J., Stoeckl, C., Thomas, T., and MacPhee, A.

Subjects

*PLASMA diagnostics, *NUCLEAR facilities, *LASER beams, *X-ray spectroscopy, *PYROLYSIS, *GRAPHITE, *SIGNAL processing

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. [ABSTRACT FROM AUTHOR]

Published

2012

10. Soft x-ray images of the laser entrance hole of ignition hohlraums.

Author

Schneider, M. B., Meezan, N. B., Alvarez, S. S., Alameda, J., Baker, S., Bell, P. M., Bradley, D. K., Callahan, D. A., Celeste, J. R., Dewald, E. L., Dixit, S. N., Döppner, T., Eder, D. C., Edwards, M. J., Fernandez-Perea, M., Gullikson, E., Haugh, M. J., Hau-Riege, S., Hsing, W., and Izumi, N.

Subjects

NUCLEAR facilities, LASER beams, ENERGY conversion, NUCLEAR fusion, X-ray spectrometers, BLACKBODY radiation

Abstract

Hohlraums are employed at the national ignition facility to convert laser energy into a thermal x-radiation drive, which implodes a fusion capsule, thus compressing the fuel. The x-radiation drive is measured with a low spectral resolution, time-resolved x-ray spectrometer, which views the region around the hohlraum's laser entrance hole. This measurement has no spatial resolution. To convert this to the drive inside the hohlraum, the size of the hohlraum's opening ('clear aperture') and fraction of the measured x-radiation, which comes from this opening, must be known. The size of the clear aperture is measured with the time integrated static x-ray imager (SXI). A soft x-ray imaging channel has been added to the SXI to measure the fraction of x-radiation emitted from inside the clear aperture. A multilayer mirror plus filter selects an x-ray band centered at 870 eV, near the peak of the x-ray spectrum of a 300 eV blackbody. Results from this channel and corrections to the x-radiation drive are discussed. [ABSTRACT FROM AUTHOR]

Published

2012

11. Early-Time Symmetry Tuning in the Presence of Cross-Beam Energy Transfer in ICF Experiments on the National Ignition Facility.

Author

Dewald, E. L., Milovich, J. L., Michel, P., Landen, O. L., Kline, J. L., Glenn, S., Jones, O., Kalantar, D. H., Pak, A., Robey, H. F., Kyrala, G. A., Divol, L., Benedetti, L. R., Holder, J., Widmann, K., Moore, A., Schneider, M. B., Döppner, T., Tommasini, R., and Bradley, D. K.

Subjects

*ENERGY transfer, *LASER beams, *SOFT X rays, *SHOCK waves

Abstract

On the National Ignition Facility, the hohlraum-driven implosion symmetry is tuned using cross-beam energy transfer (CBET) during peak power, which is controlled by applying a wavelength separation between cones of laser beams. In this Letter, we present early-time measurements of the instantaneous soft x-ray drive at the capsule using reemission spheres, which show that this wavelength separation also leads to significant CBET during the first shock, even though the laser intensities are 30X smaller than during the peak. We demonstrate that the resulting early drive P2/P0asymmetry can be minimized and tuned to <1% accuracy (well within the ±7.5% requirement for ignition) by varying the relative input powers between different cones of beams. These experiments also provide time-resolved measurements of CBET during the first 2 ns of the laser drive, which are in good agreement with radiation-hydrodynamics calculations including a linear CBET model. [ABSTRACT FROM AUTHOR]

Published

2013