Your search keyword '"Channing Huntington"' showing total 46 results

1. Nonlinear Evolution of the Ion-Weibel Instability in Interpenetrating Plasmas of CH, Al, and Cu

Author

George Swadling, P. Tzeferacos, Channing Huntington, D. D. Ryutov, Scott Wilks, Yoichi Sakawa, M. J.-E. Manuel, Soumen Ghosh, F. N. Beg, M. Adamss, R. Jonnalagadda, Bruce Remington, James Ross, H. Sio, and H.-S. Park

Subjects

Protein filament, Particle acceleration, Physics, Weibel instability, Nonlinear system, Filamentation, Physics::Plasma Physics, Physics::Space Physics, Plasma, Molecular physics, Instability, Ion

Abstract

The ion-Weibel instability is a leading candidate mechanism for the formation of collisionless shocks observed in may astrophysical systems. Experimental and computational studies have shown that the ion-Weibel instability drives current filamentation in interpenetrating plasma flows 1 , 2 with the capability to mediate collisionless shock formation and subsequent particle acceleration 3 in the lab. The present work focuses on the study of nonlinear ion-Weibel evolution under various plasma conditions through utilization of different ion species and experimental geometries. Temporally varying plasma condition are determined using benchmarked FLASH simulations. Path-integrated B-field distributions are retrieved from experimental proton images in all cases and Fourier analyzed to quantify the dominant filament scale-size and estimate the B-field strength. This new analysis methodology demonstrates that the first ~400ps of plasma interpenetration sets the spectral characteristics of ion-Weibel filamentation, and that underlying plasma conditions later in time do not significantly alter nonlinear filament evolution.

Published

2021

2. Design of a single-mode Rayleigh–Taylor instability experiment in the highly nonlinear regime

Author

C.C. Kuranz, Laura Elgin, Dov Shvarts, Guy Malamud, R. P. Drake, A. Shimony, Timothy Handy, and Channing Huntington

Subjects

Physics, Nuclear and High Energy Physics, Radiation, Scale (ratio), Design of experiments, Single-mode optical fiber, Mechanics, Laser, 01 natural sciences, Instability, Measure (mathematics), 010305 fluids & plasmas, law.invention, Nonlinear system, law, 0103 physical sciences, Rayleigh–Taylor instability, 010306 general physics

Abstract

An experimental design, intended to investigate the evolution of the single mode Rayleigh–Taylor (RT) instability in the late time regime is proposed and theoretically analyzed. The goal of the experiment is to directly measure the evolution of the shape of the interface in time, for both low and high-Atwood numbers (A ∼ 0.0.15 and A ∼ 0.6). An objective of this study is to assess the degree to which, using 10-kJ-class lasers, one can expect to observe the predicted re-acceleration of the height of structures produced by RT, which occurs in low-A simulations. The specific design presented here shows no effects of x-ray preheat, and tolerable effects of 2D rarefactions. Observation of the reacceleration effect, at the 10-kJ scale, appears marginal for the design presented here. Experiments could serve to test and validate the numerical results, and determine whether a larger-scale laser would be needed to actually observe the reacceleration effect.

Published

2019

3. Simulation and flow physics of a shocked and reshocked high-energy-density mixing layer

Author

Brian Pudliner, Robert A. Managan, Philip A. Sterne, Britton J. Olson, Oleg Schilling, Brandon Morgan, Jason D. Bender, C. Leland Ellison, Kumar Raman, Sabrina Nagel, Shon Prisbrey, Ye Zhou, Channing Huntington, David J. Erskine, Sean R. Copeland, and Christopher Wehrenberg

Subjects

Shock wave, Physics, Turbulence, Mechanical Engineering, Reynolds number, Mechanics, Condensed Matter Physics, Thermal conduction, Enstrophy, 01 natural sciences, Instability, 010305 fluids & plasmas, Physics::Fluid Dynamics, symbols.namesake, Mechanics of Materials, Physics::Space Physics, 0103 physical sciences, Turbulence kinetic energy, Compressibility, symbols, Astrophysics::Earth and Planetary Astrophysics, 010306 general physics

Abstract

This paper describes a computational investigation of multimode instability growth and multimaterial mixing induced by multiple shock waves in a high-energy-density (HED) environment, where pressures exceed 1 Mbar. The simulations are based on a series of experiments performed at the National Ignition Facility (NIF) and designed as an HED analogue of non-HED shock-tube studies of the Richtmyer–Meshkov instability and turbulent mixing. A three-dimensional computational modelling framework is presented. It treats many complications absent from canonical non-HED shock-tube flows, including distinct ion and free-electron internal energies, non-ideal equations of state, radiation transport and plasma-state mass diffusivities, viscosities and thermal conductivities. The simulations are tuned to the available NIF data, and traditional statistical quantities of turbulence are analysed. Integrated measures of turbulent kinetic energy and enstrophy both increase by over an order of magnitude due to reshock. Large contributions to enstrophy production during reshock are seen from both the baroclinic source and enstrophy–dilatation terms, highlighting the significance of fluid compressibility in the HED regime. Dimensional analysis reveals that Reynolds numbers and diffusive Peclet numbers in the HED flow are similar to those in a canonical non-HED analogue, but conductive Peclet numbers are much smaller in the HED flow due to efficient thermal conduction by free electrons. It is shown that the mechanism of electron thermal conduction significantly softens local spanwise gradients of both temperature and density, which causes a minor but non-negligible decrease in enstrophy production and small-scale mixing relative to a flow without this mechanism.

Published

2021

4. Measurement of Kinetic-Scale Current Filamentation Dynamics and Associated Magnetic Fields in Interpenetrating Plasmas

Author

George Swadling, B. B. Pollock, Colin Bruulsema, A. Birkel, James Ross, Channing Huntington, Drew Higginson, Wojciech Rozmus, H.-S. Park, H. G. Rinderknecht, Frederico Fiuza, and J. Katz

Subjects

Physics, Thomson scattering, General Physics and Astronomy, Plasma, Kinetic energy, 01 natural sciences, Ion, Magnetic field, Weibel instability, Filamentation, Physics::Plasma Physics, 0103 physical sciences, Atomic physics, 010306 general physics, Saturation (magnetic)

Abstract

We present the first local, quantitative measurements of ion current filamentation and magnetic field amplification in interpenetrating plasmas, characterizing the dynamics of the ion Weibel instability. The interaction of a pair of laser-generated, counterpropagating, collisionless, supersonic plasma flows is probed using optical Thomson scattering (TS). Analysis of the TS ion-feature revealed anticorrelated modulations in the density of the two ion streams at the spatial scale of the ion skin depth $c/{\ensuremath{\omega}}_{pi}=120\text{ }\text{ }\ensuremath{\mu}\mathrm{m}$, and a correlated modulation in the plasma current. The inferred current profile implies a magnetic field amplitude $\ensuremath{\sim}30\ifmmode\pm\else\textpm\fi{}6\text{ }\text{ }\mathrm{T}$, corresponding to $\ensuremath{\sim}1%$ of the flow kinetic energy, indicating that magnetic trapping is the dominant saturation mechanism.

Published

2020

5. Hydrodynamic and atomistic studies in support of high power laser experiments for metal ejecta recollection and interactions

Author

Brandon Morgan, Jon Eggert, Petros Tzeferacos, Alison Saunders, Hye-Sook Park, Fady Najjar, Hans Rinderknecht, Marco J. Echeverria, Tomorr Haxhimali, Channing Huntington, Suzanne Ali, and Yuan Ping

Subjects

Physics, Work (thermodynamics), Spacecraft, business.industry, Astrophysics::High Energy Astrophysical Phenomena, Free surface, Electromagnetic shielding, Hypervelocity, Mechanics, business, Ejecta, Inertial confinement fusion, Finite element method

Abstract

Shock-driven material can emit a fine spray of ejecta from its free surface. Understanding the dynamic and interaction of the metal ejecta is important to areas of study as diverse as industrial safety, astrophysics, spacecraft shielding, additive manufactur- ing and inertial confinement fusion. In this work we present results from hydrodynamic simulation studies in support of designing experiments on the OMEGA and OMEGA-EP laser platforms. The initial experimental campaign was focused on developing a platform aimed at launching hypervelocity particles. We have used a finite element formulation with ALE3D (Arbitrary Lagragian Eulerian) code in support of this campaign. Fields like pressure and velocity of elements produced in the ablated part of material are computed using the FLASH radiation-hydrodynamic code. These are then used as input in a “handshaking” region ALE code to capture shock propagation and the dynamics of the particles. As the campaign has shifted towards producing the ejecta and studying its interaction we have also undertaken an atomistic study to reveal at the ab-initio level the physics of the formation of ejecta when grooves are present in the free surface. This will be included as a framework in a multiscale study relating atomistic with the hydrodynamic scale formation of the ejecta.

Published

2020

6. Development of high power laser platforms to study metal ejecta interactions

Author

Hans Rinderknecht, Hye-Sook Park, Alison Saunders, Jon Eggert, Tomorr Haxhimali, Fady Najjar, Brandon Morgan, Channing Huntington, Suzanne Ali, and Yuan Ping

Subjects

Metal, Materials science, law, visual_art, visual_art.visual_art_medium, Ejecta, Laser, Engineering physics, law.invention, Power (physics)

Published

2020

7. How high energy fluxes may affect Rayleigh–Taylor instability growth in young supernova remnants

Author

Kirk Flippo, W. C. Wan, Channing Huntington, A. Shimony, R. P. Drake, Forrest Doss, H.-S. Park, Kumar Raman, Sallee Klein, Timothy Handy, Steve MacLaren, C.C. Kuranz, A. R. Miles, Bruce Remington, Daniel H. Kalantar, Dov Shvarts, E. M. Giraldez, Tomasz Plewa, D. C. Marion, C. M. Krauland, Shon Prisbrey, Michael Grosskopf, R. J. Wallace, Guy Malamud, Eric Harding, John Kline, Matthew Trantham, and Harry Robey

Subjects

Science, Astrophysics::High Energy Astrophysical Phenomena, General Physics and Astronomy, Astrophysics::Cosmology and Extragalactic Astrophysics, Astrophysics, Radiation, 01 natural sciences, Instability, Article, General Biochemistry, Genetics and Molecular Biology, 010305 fluids & plasmas, 0103 physical sciences, Astrophysics::Solar and Stellar Astrophysics, Rayleigh–Taylor instability, Ejecta, Supernova remnant, lcsh:Science, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics, Physics, Multidisciplinary, Radiant energy, General Chemistry, Thermal conduction, Supernova, lcsh:Q

Abstract

Energy-transport effects can alter the structure that develops as a supernova evolves into a supernova remnant. The Rayleigh–Taylor instability is thought to produce structure at the interface between the stellar ejecta and the circumstellar matter, based on simple models and hydrodynamic simulations. Here we report experimental results from the National Ignition Facility to explore how large energy fluxes, which are present in supernovae, affect this structure. We observed a reduction in Rayleigh–Taylor growth. In analyzing the comparison with supernova SN1993J, a Type II supernova, we found that the energy fluxes produced by heat conduction appear to be larger than the radiative energy fluxes, and large enough to have dramatic consequences. No reported astrophysical simulations have included radiation and heat conduction self-consistently in modeling supernova remnants and these dynamics should be noted in the understanding of young supernova remnants., Radiation and conduction are generally considered as the main energy transport mechanisms for the evolution of early supernova remnants. Here the authors experimentally show the role of electron heat transfer on the growth of Rayleigh–Taylor instability in young supernova remnants.

Published

2018

8. Extreme Hardening of Pb at High Pressure and Strain Rate

Author

Andrew Krygier, S. D. Rothman, Andrew Comley, D. C. Swift, Shon Prisbrey, Philip D. Powell, P. Graham, James McNaney, Channing Huntington, Robert E. Rudd, Christopher Wehrenberg, Bruce Remington, M. P. Hill, H.-S. Park, E. T. Gumbrell, and Athanasios Arsenlis

Subjects

Materials science, Peak pressure, Alloy, General Physics and Astronomy, engineering.material, Strain rate, Flow stress, 01 natural sciences, High pressure, Error bar, 0103 physical sciences, engineering, Hardening (metallurgy), Composite material, 010306 general physics

Abstract

We study the high-pressure strength of Pb and Pb-4wt%Sb at the National Ignition Facility. We measure Rayleigh-Taylor growth of preformed ripples ramp compressed to ∼400 GPa peak pressure, among the highest-pressure strength measurements ever reported on any platform. We find agreement with 2D simulations using the Improved Steinberg-Guinan strength model for body-centered-cubic Pb; the Pb-4wt%Sb alloy behaves similarly within the error bars. The combination of high-rate, pressure-induced hardening and polymorphism yield an average inferred flow stress of ∼3.8 GPa at high pressure, a ∼250-fold increase, changing Pb from soft to extremely strong.

Published

2019

9. Pressure and shear-induced amorphization of silicon

Author

Eric N. Hahn, H.-S. Park, Bimal K. Kad, Channing Huntington, Bruce Remington, Shiteng Zhao, Eduardo M. Bringa, Marc A. Meyers, Christopher Wehrenberg, and Karren L. More

Subjects

Phase transition, Materials science, Condensed matter physics, Silicon, Mechanical Engineering, Hydrostatic pressure, Nanocrystalline silicon, chemistry.chemical_element, Bioengineering, Nanocrystalline material, Amorphous solid, Monocrystalline silicon, Condensed Matter::Materials Science, Crystallography, chemistry, Mechanics of Materials, Chemical Engineering (miscellaneous), Partial dislocations, Engineering (miscellaneous)

Abstract

Here we report that high-power, pulsed, laser-driven shock compression of monocrystalline silicon produces directional amorphization, revealed by high-resolution transmission electron microscopy and confirmed by molecular dynamics simulations. At the lowest energy level experiment, generating a pressure of ∼4 GPa, silicon reacts elastically. At intermediate energy levels (P∼11 and 22 GPa), amorphization is observed both at the surface and directionally, along planes making angles close to the maximum shear. At the highest laser energy level explored here, (Ppeak ∼28 GPa), the recovered sample shows a nanocrystalline microstructure near the surface. This nanocrystalline structure forms by crystallization from the amorphous phase and is thought to be a post-shock phenomenon. Shear-induced lattice defects (stacking faults and twins) on crystallographic slip planes play a crucial role in the onset of amorphization. Molecular dynamics show that silicon behaves elastically until ∼10 GPa and, at slightly higher pressures, partial dislocations and stacking faults are emitted from the surface. Driven by the high-amplitude stress pulse, these defects travel inwards along specific crystallographic orientations and intersect, leading to further defect creation, additional plastic work, and, at higher pressures, amorphous bands in intersecting patterns. The typical high-pressure solid–solid phase transitions of silicon are not observed whereas the high shear stresses are relaxed by localized dislocation motion/interactions and eventually by directional amorphization, which occurs below the critical hydrostatic pressure for melting of silicon in shock compression. It is therefore proposed that the combined effects of hydrostatic and shear stresses lead to directional amorphization.

Published

2015

10. Three-dimensional signatures of self-similarity in a high-energy-density plasma shear-driven mixing layer

Author

Alexander Rasmus, John Kline, Channing Huntington, Kirk Flippo, L. Kot, Sabrina Nagel, Derek Schmidt, Forrest Doss, Barbara Devolder, C. A. Di Stefano, and E. C. Merritt

Subjects

Physics, Turbulence, Time evolution, Laminar flow, Mechanics, Condensed Matter Physics, 01 natural sciences, Instability, 010305 fluids & plasmas, 0103 physical sciences, Turbulence kinetic energy, 010306 general physics, Scaling, Inertial confinement fusion, Mixing (physics)

Abstract

A hydrodynamic shear mixing layer experiment at the National Ignition Facility had previously demonstrated Eulerian scaling of integrated, late-time quantities, including turbulent kinetic energy. In this manuscript, the experiment is repeated with new materials. Using the new dataset, we demonstrate that Euler-number scalings hold not just for late time, but dynamically throughout the experiment, for measurements in all three spatial dimensions. Incorporating the dynamic scaling leads to an enhanced calculation that the heavier of the two scaled experiments has approached three generations of mergers of its primary instability's structures and a consistent observation of such a merger in action in the lighter of the two scaled experiments. Furthermore, the improved scrutiny of the time evolution of instability structures leads to sharper estimates of turbulent kinetic energy, including a demonstration of different behaviors correlating with surface roughness (quantitatively consistent with transitions between laminar and turbulent initial states), as predicted by a Reynolds-averaged turbulent model, which evidently correctly handles the differing shock-roughness interactions to drive its internal state of the model into different regimes. Altogether, a picture arises of the analytical improvements in treating these variations (of times, densities, and roughnesses) as a unified whole and of multiple ways by which deviations from the scaling could indicate an onset of non-hydrodynamic behavior. Such deviations were not expected for these experiments (which models correctly indicated would remain hydrodynamic) but could be introduced by, for example, imposing external fields or increasing drive energy to test conditions relevant to inertial confinement fusion or other high-energy-density experiments.

Published

2020

11. FY18 LLNL Experimental Programs at Omega

Author

Andrew Krygier, James McNaney, Channing Huntington, Sheng Jiang, A. Fernandez-Pañella, Laura Robin Benedetti, E Gumbrell, Gerald Williams, Marius Millot, Shahab Khan, Gregory Kemp, Federica Coppari, H. G. Rinderknecht, H. Chen, R. Tommasini, George Swadling, Nuno Lemos, M. C. Marshall, Derek Mariscal, B. B. Pollock, R. Hua, David Martinez, R. F. Smith, Patrick Poole, M. J. MacDonald, Alison Saunders, W. W. Hsing, Laura Elgin, Klaus Widmann, Robert Heeter, E. Marley, M. Rubery, C.C. Kuranz, Suzanne Ali, Yuan Ping, Alan S. Wan, Joel V. Bernier, Otto Landen, and Amy Lazicki

Subjects

Physics, Nuclear engineering, Omega

Published

2018

12. Characterizing the modulation transfer function for X-ray radiography in high energy density experiments

Author

H.-S. Park, Andrew Krygier, E. T. Gumbrell, James McNaney, and Channing Huntington

Subjects

Materials science, business.industry, media_common.quotation_subject, Radiography, Ripple, Contrast resolution, Laser, 01 natural sciences, Instability, 010305 fluids & plasmas, law.invention, Wavelength, Optics, law, Optical transfer function, 0103 physical sciences, Contrast (vision), 010306 general physics, business, Instrumentation, media_common

Abstract

The Modulation Transfer Function (MTF) is an established means for characterizing imaging performance of X-ray radiography systems. We report on experiments using high energy, laser-driven X-ray radiography systems that assess performance using MTF values measured with the knife-edge projection method. The broadband, hard X-ray systems under study use line-projection imaging produced by narrowing the laser-generated X-ray source with a slit. We find that good contrast resolution can be achieved (the MTF = 0.5 at 75 μm wavelength) and that this performance is reproduced on different laser facilities. We also find that the MTF is sensitive both to the thickness of the line-projection slit and to the backing material thickness under the knife-edge. Both these sensitivities are due to a common mechanism, namely induced changes in the spectrally-averaged spatial widths of the X-ray source. The same line-projection system is also used on experimental campaigns measuring Rayleigh-Taylor instability growth by dynamically imaging sinusoidal, high Z micro-targets with wavelengths of 100 μm or less. By applying the measured MTF values to correct the ripple target contrast measurements, we can predict ripple growth to approximately 10% accuracy.

Published

2018

13. A platform for x-ray Thomson scattering measurements of radiation hydrodynamics experiments on the NIF

Author

Patrick Belancourt, Channing Huntington, K. H. Ma, Heath LeFevre, Paul Keiter, Carolyn Kuranz, Tilo Döppner, M. J. MacDonald, and Eric Johnsen

Subjects

Materials science, Thomson scattering, Scattering, Astrophysics::High Energy Astrophysical Phenomena, Energy flux, Electron, Thermal conduction, 01 natural sciences, 010305 fluids & plasmas, Computational physics, 0103 physical sciences, Electron temperature, 010306 general physics, National Ignition Facility, Instrumentation, Inertial confinement fusion

Abstract

We present an experimental design for a radiation hydrodynamics experiment at the National Ignition Facility that measures the electron temperature of a shocked region using the x-ray Thomson scattering technique. Previous National Ignition Facility experiments indicate a reduction in Rayleigh-Taylor instability growth due to high energy fluxes, compared to the shocked energy flux, from radiation and electron heat conduction. In order to better quantify the effects of these energy fluxes, we modified the previous experiment to allow for non-collective x-ray Thomson scattering to measure the electron temperature. Photometric calculations combined with synthetic scattering spectra demonstrate an estimated noise.

Published

2018

14. Three-Dimensional Design Simulations of a High-Energy Density Reshock Experiment at the National Ignition Facility

Author

Shon Prisbrey, Channing Huntington, Kirk Flippo, P. Wang, Sabrina Nagel, Kumar Raman, and Stephan MacLaren

Subjects

Physics, Hydrodynamic stability, Mechanical Engineering, Mechanics, 01 natural sciences, 010305 fluids & plasmas, Shock (mechanics), Computational physics, law.invention, Ignition system, law, 0103 physical sciences, Energy density, Engineering simulation, 010306 general physics, National Ignition Facility

Abstract

We present simulations of a new experimental platform at the National Ignition Facility (NIF) for studying the hydrodynamic instability growth of a high-energy density (HED) fluid interface that undergoes multiple shocks, i.e., is “reshocked.” In these experiments, indirect-drive laser cavities drive strong shocks through an initially solid, planar interface between a high-density plastic and low-density foam, in either one or both directions. The first shock turns the system into an unstable fluid interface with the premachined initial condition that then grows via the Richtmyer–Meshkov and Rayleigh–Taylor instabilities. Backlit X-ray imaging is used to visualize the instability growth at different times. Our main result is that this new HED reshock platform is established and that the initial data confirm the experiment operates in a hydrodynamic regime similar to what simulations predict. The simulations also reveal new types of edge effects that can disturb the experiment at late times and suggest ways to mitigate them.

Published

2017

15. FY17 LLNL Omega Experimental Programs

Author

Andrew Krygier, Sheng Jiang, Patrick Poole, W. W. Hsing, Amy Lazicki, Alan S. Wan, M. Schneider, James McNaney, M. Rubery, Marius Millot, Channing Huntington, Suzanne Ali, Yuan Ping, David Martinez, Federica Coppari, Otto Landen, Alison Saunders, Robert Heeter, C. Kuranz, Leonard Jarrott, H. G. Rinderknecht, H. Chen, E. Marley, Felicie Albert, Sebastien LePape, R. Hua, Dayne Fratanduono, B. B. Pollock, A. F. Panella, J. Benstead, George Swadling, Christopher Wehrenberg, R. F. Smith, Arthur Pak, E. T. Gumbrell, and Tilo Doeppner

Subjects

Physics, Nuclear engineering, Omega

Published

2017

16. Investigating iron material strength up to 1 Mbar using Rayleigh-Taylor growth measurements

Author

Jon Belof, Christopher Plechaty, Christopher Wehrenberg, Rob Cavallo, Shon Prisbrey, S. V. Weber, Bruce Remington, H S Park, Brian Maddox, R. J. Wallace, D. W. Swift, Michael Wilson, Robert E. Rudd, K. J. M. Blobaum, Channing Huntington, and Natalie Kostinski

Subjects

symbols.namesake, Phase transition, Crystallography, Amplitude, Materials science, Ripple, symbols, Melting point, Rayleigh scattering, Composite material, Deformation (engineering), Strength of materials, Instability

Abstract

The solid-solid phase transition between the bcc (α) and hcp (e) lattice structures in iron is known to occur as the material is compressed. When kept below its melting point, an effective increase in the macroscopic strength of the material accompanies this phase transition. Understanding the material strength of iron throughout the deformation process presents a significant computational challenge, but is important for improving models of planetary structure, including interpretation of seismic measurements taken through our own Earth’s core.To explore the strength of iron at high pressures and strain rates, we have developed the IronRT campaign at the OMEGA laser [1]. This laser-driven platform produces pressure greater than 1 Mbar on a thin Fe disk with a sinusoidal ripple pattern imposed on its face. These ripples seed the Rayleigh-Taylor (RT) instability, the growth of which is suppressed by the material strength of the sample. The amplitude of the ripples is diagnosed with high-energy x-ray radiogr...

Published

2017

17. Proton pinhole imaging on the National Ignition Facility

Author

B. B. Pollock, C. K. Li, Johan Frenje, H.-S. Park, David Turnbull, James Ross, R. D. Petrasso, Drew Higginson, Channing Huntington, Dmitri Ryutov, Scott Wilks, H. G. Rinderknecht, Fredrick Seguin, Frederico Fiuza, Bruce Remington, and Alex Zylstra

Subjects

Physics, Proton, business.industry, Wiener deconvolution, Plasma, 01 natural sciences, 010305 fluids & plasmas, Optics, Physics::Plasma Physics, 0103 physical sciences, Pinhole (optics), Plasma diagnostics, Astrophysical plasma, Deconvolution, 010306 general physics, National Ignition Facility, business, Instrumentation

Abstract

Pinhole imaging of large (mm scale) carbon-deuterium (CD) plasmas by proton self-emission has been used for the first time to study the microphysics of shock formation, which is of astrophysical relevance. The 3 MeV deuterium-deuterium (DD) fusion proton self-emission from these plasmas is imaged using a novel pinhole imaging system, with up to five different 1 mm diameter pinholes positioned 25 cm from target-chamber center. CR39 is used as the detector medium, positioned at 100 cm distance from the pinhole for a magnification of 4 ×. A Wiener deconvolution algorithm is numerically demonstrated and used to interpret the images. When the spatial morphology is known, this algorithm accurately reproduces the size of features larger than about half the pinhole diameter. For these astrophysical plasma experiments on the National Ignition Facility, this provides a strong constraint on simulation modeling of the experiment.

Published

2016

18. Turbulent mixing and transition criteria of flows induced by hydrodynamic instabilities

Author

Bruce Remington, M. Aaron Skinner, Omar Hurricane, Daniel S. Clark, S. Gail Glendinning, Timothy T. Clark, Ye Zhou, Channing Huntington, and Andris Dimits

Subjects

Physics, Turbulent mixing, Process (engineering), Turbulence, Transition (fiction), Infinitesimal, Mechanics, Condensed Matter Physics, 01 natural sciences, Instability, 010305 fluids & plasmas, Physics::Fluid Dynamics, Nonlinear system, 0103 physical sciences, 010306 general physics, Mixing (physics)

Abstract

In diverse areas of science and technology, including inertial confinement fusion (ICF), astrophysics, geophysics, and engineering processes, turbulent mixing induced by hydrodynamic instabilities is of scientific interest as well as practical significance. Because of the fundamental roles they often play in ICF and other applications, three classes of hydrodynamic instability-induced turbulent flows—those arising from the Rayleigh-Taylor, Richtmyer-Meshkov, and Kelvin-Helmholtz instabilities—have attracted much attention. ICF implosions, supernova explosions, and other applications illustrate that these phases of instability growth do not occur in isolation, but instead are connected so that growth in one phase feeds through to initiate growth in a later phase. Essentially, a description of these flows must encompass both the temporal and spatial evolution of the flows from their inception. Hydrodynamic instability will usually start from potentially infinitesimal spatial perturbations, will eventually transition to a turbulent flow, and then will reach a final state of a true multiscale problem. Indeed, this change in the spatial scales can be vast, with hydrodynamic instability evolving from just a few microns to thousands of kilometers in geophysical or astrophysical problems. These instabilities will evolve through different stages before transitioning to turbulence, experiencing linear, weakly, and highly nonlinear states. The challenges confronted by researchers are enormous. The inherent difficulties include characterizing the initial conditions of such flows and accurately predicting the transitional flows. Of course, fully developed turbulence, a focus of many studies because of its major impact on the mixing process, is a notoriously difficult problem in its own right. In this pedagogical review, we will survey challenges and progress, and also discuss outstanding issues and future directions.

Published

2019

19. Kinetic effects on neutron generation in moderately collisional interpenetrating plasma flows

Author

George Swadling, S. V. Weber, H. G. Rinderknecht, Brandon Lahmann, Drew Higginson, R. D. Petrasso, Youichi Sakawa, A. Link, Robert Hatarik, J. D. Kilkenny, B. B. Pollock, E. P. Hartouni, Frederico Fiuza, Bruce Remington, Alex Zylstra, Dmitri Ryutov, H.-S. Park, Channing Huntington, Scott Wilks, Hong Sio, James Ross, and C. K. Li

Subjects

Physics, Plasma, Condensed Matter Physics, Kinetic energy, 01 natural sciences, Instability, Molecular physics, 010305 fluids & plasmas, Ion, Distribution function, Physics::Plasma Physics, 0103 physical sciences, Nuclear fusion, Neutron, Plasma diagnostics, 010306 general physics

Abstract

Collisional kinetic modifications of ion distributions in interpenetrating flows are investigated by irradiating two opposing targets, either CD/CD or CD/CH, on the National Ignition Facility. In the CD/CD case, neutron time-of-flight diagnostics are successfully used to infer the ion temperature, 5–6 keV, and velocity, 500 km/s per flow, of the flows using a multi-fluid approximation of beam-beam nuclear fusion. These values are found to be in agreement with simulations and other diagnostics. However, for CD/CH, the multi-fluid assumption breaks down, as fusion is quasi-thermonuclear in this case and thus more dependent on the details of the ion velocity distribution. Using kinetic-ion, hydrodynamic-electron, and hybrid particle-in-cell modeling, this is found to be partially due to a skewed deviation from a Maxwellian in the ion velocity distribution function resulting from ion-ion collisions. This skew causes a downshift in the mean neutron velocity that partially resolves the observation in the CD/CH case. We note that the discrepancy is not completely resolved via collisional effects alone and may be a signature of collisionless electromagnetic interactions such as the Weibel-filamentation instability.

Published

2019

20. Transition from Collisional to Collisionless Regimes in Interpenetrating Plasma Flows on the National Ignition Facility

Author

Michael Rosenberg, Dustin Froula, Jena Meinecke, Dmitri Ryutov, R. P. Drake, C. K. Li, M. C. Levy, Carolyn Kuranz, B. B. Pollock, Frederico Fiuza, H. Takabe, James Ross, Scott Wilks, M. Koenig, Channing Huntington, Brandon Lahmann, Bruce Remington, H.-S. Park, Alex Zylstra, H. G. Rinderknecht, Youichi Sakawa, Daniel H. Kalantar, Anatoly Spitkovsky, A. Link, David Turnbull, Hong Sio, Gianluca Gregori, R. D. Petrasso, Drew Higginson, Taichi Morita, George Swadling, S. V. Weber, and Robert Hatarik

Subjects

Nuclear reaction, Physics, Shock (fluid dynamics), Mean free path, Astrophysics::High Energy Astrophysical Phenomena, General Physics and Astronomy, Plasma, 01 natural sciences, Instability, 010305 fluids & plasmas, symbols.namesake, Mach number, Filamentation, Physics::Plasma Physics, Physics::Space Physics, 0103 physical sciences, symbols, Neutron, Atomic physics, 010306 general physics

Abstract

A study of the transition from collisional to collisionless plasma flows has been carried out at the National Ignition Facility using high Mach number (M>4) counterstreaming plasmas. In these experiments, CD-CD and CD-CH planar foils separated by 6-10 mm are irradiated with laser energies of 250 kJ per foil, generating ∼1000 km/s plasma flows. Varying the foil separation distance scales the ion density and average bulk velocity and, therefore, the ion-ion Coulomb mean free path, at the interaction region at the midplane. The characteristics of the flow interaction have been inferred from the neutrons and protons generated by deuteron-deuteron interactions and by x-ray emission from the hot, interpenetrating, and interacting plasmas. A localized burst of neutrons and bright x-ray emission near the midpoint of the counterstreaming flows was observed, suggesting strong heating and the initial stages of shock formation. As the separation of the CD-CH foils increases we observe enhanced neutron production compared to particle-in-cell simulations that include Coulomb collisions, but do not include collective collisionless plasma instabilities. The observed plasma heating and enhanced neutron production is consistent with the initial stages of collisionless shock formation, mediated by the Weibel filamentation instability.

Published

2016

21. Laboratory astrophysical collisionless shock experiments on Omega and NIF

Author

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

Subjects

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

Abstract

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

Published

2016

22. Late-Time Mixing Sensitivity to Initial Broadband Surface Roughness in High-Energy-Density Shear Layers

Author

Gerald Rivera, Sabrina Nagel, Deanna Capelli, Steve MacLaren, Forrest Doss, Eric Loomis, Randall B. Randolph, Barbara Devolder, E. C. Merritt, Channing Huntington, Tana Cardenas, L. Kot, John Kline, Derek Schmidt, T. S. Perry, Kirk A. Flippo, F. Fierro, and Thomas J. Murphy

Subjects

Materials science, Turbulence, business.industry, Electronvolt, General Physics and Astronomy, 01 natural sciences, Molecular physics, 010305 fluids & plasmas, Physics::Fluid Dynamics, Optics, Shear (geology), TRACER, 0103 physical sciences, Surface roughness, Supersonic speed, 010306 general physics, National Ignition Facility, business, FOIL method

Abstract

Using a large volume high-energy-density fluid shear experiment ($8.5\text{ }\text{ }{\mathrm{cm}}^{3}$) at the National Ignition Facility, we have demonstrated for the first time the ability to significantly alter the evolution of a supersonic sheared mixing layer by controlling the initial conditions of that layer. By altering the initial surface roughness of the tracer foil, we demonstrate the ability to transition the shear mixing layer from a highly ordered system of coherent structures to a randomly ordered system with a faster growing mix layer, indicative of strong mixing in the layer at a temperature of several tens of electron volts and at near solid density. Simulations using a turbulent-mix model show good agreement with the experimental results and poor agreement without turbulent mix.

Published

2016

23. Proton imaging of an electrostatic field structure formed in laser-produced counter-streaming plasmas

Author

Gianluca Gregori, N. Quiros, W. C. Wan, James Ross, Hye-Sook Park, Alexander Pelka, David Martinez, Jena Meinecke, M. C. Levy, C. D. Murphy, L. Steele, Brian Reville, Carolyn Kuranz, Radu Presura, Nigel Woolsey, Frederico Fiuza, Christopher Plechaty, Nathan Kugland, Michel Koenig, Francesco Miniati, R. P. Drake, Dmitri Ryutov, Youichi Sakawa, Bruce Remington, Channing Huntington, Hideaki Takabe, Taichi Morita, T. Ishikawa, R. Crowston, and Yuta Yamaura

Subjects

History, 010504 meteorology & atmospheric sciences, Field (physics), Proton, Nuclear Theory, Electron, Physics and Astronomy(all), Kinetic energy, 01 natural sciences, Education, Physics::Plasma Physics, Electric field, 0103 physical sciences, Nuclear Experiment, 010306 general physics, 0105 earth and related environmental sciences, Chemistry, Plasma, Computer Science Applications, Shock (mechanics), Physics::Space Physics, Physics::Accelerator Physics, Atomic physics, Nucleon

Abstract

We report the measurements of electrostatic field structures associated with an electrostatic shock formed in laser-produced counter-streaming plasmas with proton imaging. The thickness of the electrostatic structure is estimated from proton images with different proton kinetic energies from 4.7 MeV to 10.7 MeV. The width of the transition region is characterized by electron scale length in the laser-produced plasma, suggesting that the field structure is formed due to a collisionless electrostatic shock., Journal of Physics: Conference Series, 688 (1), ISSN:1742-6588, ISSN:1742-6596

Published

2016

24. FY15 LLNL OMEGA Experimental Programs

Author

Kevin Baker, Otto Landen, Peter M. Celliers, Alan S. Wan, B. B. Pollock, David Martinez, Klaus Widmann, H.-S. Park, W. W. Hsing, Robert Heeter, R. G. Kraus, Gilbert Collins, James McNaney, Dayne Fratanduono, M. A. Barrios, Channing Huntington, Daniel Casey, Martha A. Beckwith, Federica Coppari, J. Frenje, Yuan Ping, Marius Millot, Amy Lazicki, K. B. Fournier, R. F. Smith, Christopher Wehrenberg, H. Chen, and Arthur Pak

Subjects

Nuclear engineering, Omega

Published

2015

25. Late-time mixing and turbulent behavior in high-energy-density shear experiments at high Atwood numbers

Author

Derek Schmidt, Kirk Flippo, Barbara Devolder, L. Kot, Steve MacLaren, F. Fierro, Forrest Doss, Tana Cardenas, Channing Huntington, Susan Kurien, Alexander Rasmus, C. A. Di Stefano, T. S. Perry, John Kline, Deanna Capelli, Tiffany Desjardins, Thomas J. Murphy, Sabrina Nagel, Paul A. Bradley, E. C. Merritt, Eric Loomis, and Randall B. Randolph

Subjects

Physics, Turbulence, Eulerian path, Plasma, Mechanics, Radiation, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Vortex, symbols.namesake, 0103 physical sciences, Turbulence kinetic energy, symbols, 010306 general physics, National Ignition Facility, Scaling

Abstract

The LANL Shear Campaign uses millimeter-scale initially solid shock tubes on the National Ignition Facility to conduct high-energy-density hydrodynamic plasma experiments, capable of reaching energy densities exceeding 100 kJ/cm3. These shock-tube experiments have for the first time reproduced spontaneously emergent coherent structures due to shear-based fluid instabilities [i.e., Kelvin-Helmholtz (KH)], demonstrating hydrodynamic scaling over 8 orders of magnitude in time and velocity. The KH vortices, referred to as “rollers,” and the secondary instabilities, referred to as “ribs,” are used to understand the turbulent kinetic energy contained in the system. Their evolution is used to understand the transition to turbulence and that transition's dependence on initial conditions. Experimental results from these studies are well modeled by the RAGE (Radiation Adaptive Grid Eulerian) hydro-code using the Besnard-Harlow-Rauenzahn turbulent mix model. Information inferred from both the experimental data and the mix model allows us to demonstrate that the specific Turbulent Kinetic Energy (sTKE) in the layer, as calculated from the plan-view structure data, is consistent with the mixing width growth and the RAGE simulations of sTKE.

Published

2018

26. Ablative stabilization of Rayleigh-Taylor instabilities resulting from a laser-driven radiative shock

Author

Kirk Flippo, H.-S. Park, Steve MacLaren, Forrest Doss, C. A. Di Stefano, Shon Prisbrey, John Kline, A. R. Miles, Guy Malamud, R. P. Drake, A. Shimony, Channing Huntington, W. C. Wan, Sallee Klein, Bruce Remington, Kumar Raman, Daniel H. Kalantar, Carolyn Kuranz, Dov Shvarts, Harry Robey, and Matthew Trantham

Subjects

Physics, Astrophysics::High Energy Astrophysical Phenomena, Mechanics, Condensed Matter Physics, Thermal conduction, 01 natural sciences, Instability, 010305 fluids & plasmas, Shock (mechanics), Radiative flux, 0103 physical sciences, Radiative transfer, Laser power scaling, 010306 general physics, National Ignition Facility, Inertial confinement fusion, Astrophysics::Galaxy Astrophysics

Abstract

The Rayleigh-Taylor (RT) instability is a common occurrence in nature, notably in astrophysical systems like supernovae, where it serves to mix the dense layers of the interior of an exploding star with the low-density stellar wind surrounding it, and in inertial confinement fusion experiments, where it mixes cooler materials with the central hot spot in an imploding capsule and stifles the desired nuclear reactions. In both of these examples, the radiative flux generated by strong shocks in the system may play a role in partially stabilizing RT instabilities. Here, we present experiments performed on the National Ignition Facility, designed to isolate and study the role of radiation and heat conduction from a shock front in the stabilization of hydrodynamic instabilities. By varying the laser power delivered to a shock-tube target with an embedded, unstable interface, the radiative fluxes generated at the shock front could be controlled. We observe decreased RT growth when the shock significantly heats t...

Published

2018

27. Lattice-level observation of the elastic-to-plastic relaxation process with subnanosecond resolution in shock-compressed Ta using time-resolvedin situLaue diffraction

Author

Federica Coppari, Nathan R. Barton, Robert E. Rudd, Andrew Comley, Channing Huntington, C. Plechaty, H.-S. Park, Shon Prisbrey, Christopher Wehrenberg, Dayne Fratanduono, Brian Maddox, and Bruce Remington

Subjects

In situ, Condensed Matter::Materials Science, Molecular dynamics, Materials science, Condensed matter physics, Lattice (order), X-ray crystallography, Nucleation, Shear stress, Flow stress, Dislocation, Condensed Matter Physics, Electronic, Optical and Magnetic Materials

Abstract

We report direct lattice-level measurements of plastic relaxation kinetics through time-resolved, in situ Laue diffraction of shock-compressed single-crystal [001] Ta at pressures of 27--210 GPa. For a 50-GPa shock, a range of shear strains is observed extending up to the uniaxial limit for early data points ($l0.6$ ns), and the average shear strain relaxes to a near steady state over $\ensuremath{\sim}1$ ns. For 80- and 125-GPa shocks, the measured shear strains are fully relaxed already at 200 ps, consistent with rapid relaxation associated with the predicted threshold for homogeneous nucleation of dislocations occurring at shock pressure $\ensuremath{\sim}65$ GPa. The relaxation rate and shear stresses are used to estimate the dislocation density, and these quantities are compared to the results of other high-pressure work, flow stress models, and molecular dynamics simulations.

Published

2015

28. Grain-Size-Independent Plastic Flow at Ultrahigh Pressures and Strain Rates

Author

Mark May, Greg Randall, Nathan R. Barton, Robert Cavallo, Abbas Nikroo, Bruce Remington, R. J. Wallace, E. M. Giraldez, Christopher Wehrenberg, C. Plechaty, Channing Huntington, Robert E. Rudd, K. J. M. Blobaum, Michael Farrell, Athanasios Arsenlis, J.N. Florando, George T. Gray, Jonathan L. Belof, M. J. Wilson, Brian Maddox, Shon Prisbrey, H.-S. Park, Bassem S. El-Dasher, and Andrew Comley

Subjects

Materials science, Condensed matter physics, Tantalum, General Physics and Astronomy, chemistry.chemical_element, Models, Theoretical, Strain rate, Flow stress, Plasticity, Omega, Grain size, Metal, chemistry, Metals, visual_art, Materials Testing, Hardening (metallurgy), visual_art.visual_art_medium, Particle Size

Abstract

A basic tenet of material science is that the flow stress of a metal increases as its grain size decreases, an effect described by the Hall-Petch relation. This relation is used extensively in material design to optimize the hardness, durability, survivability, and ductility of structural metals. This Letter reports experimental results in a new regime of high pressures and strain rates that challenge this basic tenet of mechanical metallurgy. We report measurements of the plastic flow of the model body-centered-cubic metal tantalum made under conditions of high pressure ($g100\text{ }\text{ }\mathrm{GPa}$) and strain rate ($\ensuremath{\sim}1{0}^{7}\text{ }\text{ }{\mathrm{s}}^{\ensuremath{-}1}$) achieved by using the Omega laser. Under these unique plastic deformation (``flow'') conditions, the effect of grain size is found to be negligible for grain sizes $g0.25\text{ }\text{ }\ensuremath{\mu}\mathrm{m}$ sizes. A multiscale model of the plastic flow suggests that pressure and strain rate hardening dominate over the grain-size effects. Theoretical estimates, based on grain compatibility and geometrically necessary dislocations, corroborate this conclusion.

Published

2015

29. Magnetic field production via the Weibel instability in interpenetrating plasma flows

Author

B. B. Pollock, George Swadling, Hong Sio, Channing Huntington, H. Takabe, James Ross, Anatoly Spitkovsky, Drew Higginson, Gianluca Gregori, Youichi Sakawa, Scott Wilks, H.-S. Park, C. Ruyer, H. G. Rinderknecht, Dmitri Ryutov, Frederico Fiuza, Bruce Remington, Alex Zylstra, J. Park, and Mario Manuel

Subjects

Electromagnetic field, Physics, Shock (fluid dynamics), Astrophysics::High Energy Astrophysical Phenomena, Plasma, Astrophysics, Condensed Matter Physics, 01 natural sciences, Magnetic field, Computational physics, Weibel instability, Shock waves in astrophysics, Two-stream instability, Physics::Plasma Physics, Physics::Space Physics, 0103 physical sciences, 010306 general physics, Gamma-ray burst, 010303 astronomy & astrophysics, Astrophysics::Galaxy Astrophysics

Abstract

Many astrophysical systems are effectively “collisionless,” that is, the mean free path for collisions between particles is much longer than the size of the system. The absence of particle collisions does not preclude shock formation, however, as shocks can be the result of plasma instabilities that generate and amplify electromagnetic fields. The magnetic fields required for shock formation may either be initially present, for example, in supernova remnants or young galaxies, or they may be self-generated in systems such as gamma-ray bursts (GRBs). In the case of GRB outflows, the Weibel instability is a candidate mechanism for the generation of sufficiently strong magnetic fields to produce shocks. In experiments on the OMEGA Laser, we have demonstrated a quasi-collisionless system that is optimized for the study of the non-linear phase of Weibel instability growth. Using a proton probe to directly image electromagnetic fields, we measure Weibel-generated magnetic fields that grow in opposing, initially unmagnetized plasma flows. The collisionality of the system is determined from coherent Thomson scattering measurements, and the data are compared to similar measurements of a fully collisionless system. The strong, persistent Weibel growth observed here serves as a diagnostic for exploring large-scale magnetic field amplification and the microphysics present in the collisional-collisionless transition.

Published

2017

30. Spectral content of buried Ag foils at 10(16) W/cm(2) laser illumination

Author

Bruce Remington, Channing Huntington, Shon Prisbrey, H.-S. Park, and Brian Maddox

Subjects

Physics, Thomson scattering, Astrophysics::High Energy Astrophysical Phenomena, Electron shell, Plasma, Laser, Electromagnetic radiation, Spectral line, law.invention, law, Ionization, Atomic physics, Instrumentation, Inertial confinement fusion

Abstract

Sources of 5-12 keV thermal Heα x-rays are readily generated by laser irradiation of mid-Z foils at intensities10(14) W/cm(2), and are widely used as probes for inertial confinement fusion and high-energy-density experiments. Higher energy 17-50 keV x-ray sources are efficiently produced from "cold" Kα emission using short pulse, petawatt lasers at intensities10(18) W/cm(2) [H.-S. Park, B. R. Maddox et al., "High-resolution 17-75 keV backlighters for high energy density experiments," Phys. Plasmas 15(7), 072705 (2008); B. R. Maddox, H. S. Park, B. A. Remington et al., "Absolute measurements of x-ray backlighter sources at energies above 10 keV," Phys. Plasmas 18(5), 056709 (2011)]. However, when long pulse (1 ns) lasers are used with Z30 elements, the spectrum contains contributions from both K shell transitions and from ionized atomic states. Here we show that by sandwiching a silver foil between layers of high-density carbon, the ratio of Kα:Heα in the x-ray spectrum is significant increased over directly illuminated Ag foils, with narrower lines from K-shell transitions. Additionally, the emission volume is more localized for the sandwiched target, producing a more planar x-ray sheet. This technique may be useful for generating probes requiring spectral purity and a limited spatial extent, for example, in incoherent x-ray Thomson scattering experiments.

Published

2014

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

Author

H.-S. Park, Otto Landen, M. A. Barrios, Gilbert Collins, Ryan Rygg, Ronald M. Epstein, K. B. Fournier, Channing Huntington, R. F. Smith, Jon Eggert, Dayne Fratanduono, D. K. Bradley, Amy Lazicki, and Susan Regan

Subjects

Materials science, law, Energy conversion efficiency, X-ray, Electron shell, Atomic physics, Spectroscopy, Laser, Kinetic energy, National Ignition Facility, Instrumentation, Spectral line, law.invention

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 × 10(15) W/cm(2). 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.

Published

2014

32. FY14 LLNL OMEGA Experimental Programs

Author

Otto Landen, H. Chen, Sabrina Nagel, James Ross, Alan S. Wan, L. A. Bernstein, M. A. Barrios, R. G. Kraus, Federica Coppari, J. R. Rygg, W. W. Hsing, Kevin Baker, Robert Heeter, B. B. Pollock, A. Jenei, Alex Zylstra, K. B. Fournier, David Martinez, Peter M. Celliers, M. G. Johnson, Gilbert Collins, F. Pérez, H.-S. Park, A. S. Moore, R. F. Smith, D. P. McNabb, P. K. Patel, Yuan Ping, Tammy Ma, Channing Huntington, Marius Millot, Gregory V. Brown, and Dayne Fratanduono

Subjects

Nuclear engineering, Omega

Published

2014

33. Development of an Interpretive Simulation Tool for the Proton Radiography Technique

Author

M. C. Levy, David Martinez, H.-S. Park, Channing Huntington, Nathan Kugland, Frederico Fiuza, Dmitri Ryutov, Matthew G. Baring, Scott Wilks, and Jason Ross

Subjects

Electromagnetic field, Physics, Proton, FOS: Physical sciences, Field strength, Plasma, Physics - Plasma Physics, Connection (mathematics), Computational physics, Weibel instability, Plasma Physics (physics.plasm-ph), Cover (topology), Development (differential geometry), Instrumentation

Abstract

Proton radiography is a useful diagnostic of high energy density (HED) plasmas under active theoretical and experimental development. In this paper we describe a new simulation tool that interacts realistic laser-driven point-like proton sources with three dimensional electromagnetic fields of arbitrary strength and structure and synthesizes the associated high resolution proton radiograph. The present tool's numerical approach captures all relevant physics effects, including effects related to the formation of caustics. Electromagnetic fields can be imported from PIC or hydrodynamic codes in a streamlined fashion, and a library of electromagnetic field `primitives' is also provided. This latter capability allows users to add a primitive, modify the field strength, rotate a primitive, and so on, while quickly generating a high resolution radiograph at each step. In this way, our tool enables the user to deconstruct features in a radiograph and interpret them in connection to specific underlying electromagnetic field elements. We show an example application of the tool in connection to experimental observations of the Weibel instability in counterstreaming plasmas, using $\sim 10^8$ particles generated from a realistic laser-driven point-like proton source, imaging fields which cover volumes of $\sim10 $ mm$^3$. Insights derived from this application show that the tool can support understanding of HED plasmas., Figures and tables related to the Appendix are included in the published journal article

Published

2014

34. FY13 LLNL OMEGA Experimental Programs

Author

W Hsing, P Celliers, Christopher Wehrenberg, D. Fratanduono, A. Wan, G. W. Collins, A Lazicki, C Plechaty, A Pak, F. Pérez, O. Landen, G Brown, R. F. Heeter, D Casey, J. Hawreliak, K Baker, H S Park, J. S. Ross, K B Fournier, H Rinderknecht, T Ma, A. Moore, R. Tommasini, J. R. Rygg, Smalyuk, Channing Huntington, Y Ping, A. Zylstra, M May, and R Patterson

Subjects

Physics, Nanotechnology, Omega, Engineering physics

Published

2013

35. Observation of magnetic field generation via the Weibel instability in interpenetrating plasma flows

Author

Taichi Morita, Hideaki Takabe, C. Plechaty, Channing Huntington, M. C. Levy, Gianluca Gregori, Dmitri Ryutov, Jena Meinecke, Anatoly Spitkovsky, R. D. Petrasso, Chikang Li, Youichi Sakawa, Carolyn Kuranz, H.-S. Park, Jason Ross, Dustin Froula, Frederico Fiuza, Bruce Remington, Alex Zylstra, Nathan Kugland, and R. P. Drake

Subjects

High Energy Astrophysical Phenomena (astro-ph.HE), Shock wave, Physics, Astrophysical Processes, Astrophysics::High Energy Astrophysical Phenomena, FOS: Physical sciences, General Physics and Astronomy, Plasma, 7. Clean energy, Physics - Plasma Physics, Magnetic field, Plasma Physics (physics.plasm-ph), Weibel instability, Two-stream instability, Classical mechanics, Physics::Plasma Physics, Quantum electrodynamics, Physics::Space Physics, Astrophysics - High Energy Astrophysical Phenomena, Mechanism (sociology)

Abstract

Collisionless shocks can be produced as a result of strong magnetic fields in a plasma flow, and therefore are common in many astrophysical systems. The Weibel instability is one candidate mechanism for the generation of sufficiently strong fields to create a collisionless shock. Despite their crucial role in astrophysical systems, observation of the magnetic fields produced by Weibel instabilities in experiments has been challenging. Using a proton probe to directly image electromagnetic fields, we present evidence of Weibel-generated magnetic fields that grow in opposing, initially unmagnetized plasma flows from laser-driven laboratory experiments. Three-dimensional particle-in-cell simulations reveal that the instability efficiently extracts energy from the plasma flows, and that the self-generated magnetic energy reaches a few percent of the total energy in the system. This result demonstrates an experimental platform suitable for the investigation of a wide range of astrophysical phenomena, including collisionless shock formation in supernova remnants, large-scale magnetic field amplification, and the radiation signature from gamma-ray bursts.

Published

2013

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

Author

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

Subjects

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

Abstract

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

Published

2016

37. eHXI: a permanently installed, hard x-ray imager for the National Ignition Facility

Author

G. LaCaille, Cliff Thomas, Otto Landen, E. L. Dewald, N. Izumi, Perry M. Bell, B. Bachmann, H.-S. Park, N. E. Palmer, John R. Celeste, Matthias Hohenberger, Scott Burns, Tilo Döppner, Felicie Albert, Laurent Divol, Robert Chow, and Channing Huntington

Subjects

Physics, High energy, business.industry, Detector, X-ray, Implosion, 01 natural sciences, 010305 fluids & plasmas, Optics, Hohlraum, 0103 physical sciences, 010306 general physics, business, National Ignition Facility, Instrumentation, Inertial confinement fusion, Hot electron, Mathematical Physics

Abstract

We have designed and built a multi-pinhole imaging system for high energy x-rays (≥ 50 keV) that is permanently installed in the equatorial plane outside of the target chamber at the National Ignition Facility (NIF). It records absolutely-calibrated, time-integrated x-ray images with the same line-of-sight as the multi-channel, spatially integrating hard x-ray detector FFLEX [McDonald et al., Rev. Sci. Instrum. 75 (2004) 3753], having a side view of indirect-drive inertial confinement fusion (ICF) implosion targets. The equatorial hard x-ray imager (eHXI) has recorded images on the majority of ICF implosion experiments since May 2011. Lastly, eHXI provides valuable information on hot electron distribution in hohlraum experiments, target alignment, potential hohlraum drive asymmetries and serves as a long term reference for the FFLEX diagnostics.

Published

2016

38. Three- and two-dimensional simulations of counter-propagating shear experiments at high energy densities at the National Ignition Facility

Author

Ye Zhou, Channing Huntington, Forrest Doss, Kirk Flippo, P. Wang, Kumar Raman, and Stephan MacLaren

Subjects

Physics, Numerical analysis, media_common.quotation_subject, Reynolds number, Mechanics, Condensed Matter Physics, Asymmetry, symbols.namesake, Shear (geology), symbols, Statistical physics, Navier–Stokes equations, Shock tube, Shear flow, National Ignition Facility, media_common

Abstract

Three- and two-dimensional numerical studies have been carried out to simulate recent counter-propagating shear flow experiments on the National Ignition Facility. A multi-physics three-dimensional, time-dependent radiation hydrodynamics simulation code is used. Using a Reynolds Averaging Navier-Stokes model, we show that the evolution of the mixing layer width obtained from the simulations agrees well with that measured from the experiments. A sensitivity study is conducted to illustrate a 3D geometrical effect that could confuse the measurement at late times, if the energy drives from the two ends of the shock tube are asymmetric. Implications for future experiments are discussed.

Published

2015

39. Collisionless shock experiments with lasers and observation of Weibel instabilitiesa)

Author

H. Takabe, James Ross, B. B. Pollock, M. C. Levy, C. K. Li, Hans Rinderknecht, D. Q. Lamb, H.-S. Park, Channing Huntington, Anatoly Spitkovsky, Petros Tzeferacos, David Turnbull, R. D. Petrasso, Youichi Sakawa, Carolyn Kuranz, Taichi Morita, Jena Meinecke, Dustin Froula, Nathan Kugland, Michael Rosenberg, R. P. Drake, Frederico Fiuza, Dmitri Ryutov, S. V. Weber, M. Koenig, Bruce Remington, Alex Zylstra, and Gianluca Gregori

Subjects

Shock wave, Physics, Astrophysics::High Energy Astrophysical Phenomena, Plasma, Astrophysics, Condensed Matter Physics, Magnetic field, Shock waves in astrophysics, Weibel instability, Supernova, Physics::Plasma Physics, Physics::Space Physics, Astrophysical plasma, Gamma-ray burst

Abstract

Astrophysical collisionless shocks are common in the universe, occurring in supernova remnants, gamma ray bursts, and protostellar jets. They appear in colliding plasma flows when the mean free path for ion-ion collisions is much larger than the system size. It is believed that such shocks could be mediated via the electromagnetic Weibel instability in astrophysical environments without pre-existing magnetic fields. Here, we present laboratory experiments using high-power lasers and investigate the dynamics of high-Mach-number collisionless shock formation in two interpenetrating plasma streams. Our recent proton-probe experiments on Omega show the characteristic filamentary structures of the Weibel instability that are electromagnetic in nature with an inferred magnetization level as high as ∼1% [C. M. Huntington et al., “Observation of magnetic field generation via the weibel instability in interpenetrating plasma flows,” Nat. Phys. 11, 173–176 (2015)]. These results imply that electromagnetic instabilities are significant in the interaction of astrophysical conditions.

Published

2015

40. Developing a bright 17 keV x-ray source for probing high-energy-density states of matter at high spatial resolution

Author

Channing Huntington, Christopher Wehrenberg, M. A. Barrios, Brian Maddox, Dave Braun, Bruce Remington, R. Benedetti, Matthias Hohenberger, Otto Landen, H.-S. Park, and Susan Regan

Subjects

Physics, Aperture, business.industry, Resolution (electron density), Energy conversion efficiency, Condensed Matter Physics, Laser, Spectral line, Pulse (physics), law.invention, Optics, law, National Ignition Facility, business, Image resolution

Abstract

A set of experiments were performed on the National Ignition Facility (NIF) to develop and optimize a bright, 17 keV x-ray backlighter probe using laser-irradiated Nb foils. High-resolution one-dimensional imaging was achieved using a 15 μm wide slit in a Ta substrate to aperture the Nb Heα x-rays onto an open-aperture, time integrated camera. To optimize the x-ray source for imaging applications, the effect of laser pulse shape and spatial profile on the target was investigated. Two laser pulse shapes were used—a “prepulse” shape that included a 3 ns, low-intensity laser foot preceding the high-energy 2 ns square main laser drive, and a pulse without the laser foot. The laser spatial profile was varied by the use of continuous phase plates (CPPs) on a pair of shots compared to beams at best focus, without CPPs. A comprehensive set of common diagnostics allowed for a direct comparison of imaging resolution, total x-ray conversion efficiency, and x-ray spectrum between shots. The use of CPPs was seen to re...

Published

2015

41. Thomson scattering measurements from asymmetric interpenetrating plasma flows

Author

J. S. Ross, Frederico Fiuza, Laurent Divol, H.-S. Park, John Moody, Channing Huntington, and Dmitri Ryutov

Subjects

Electron density, Materials science, Thomson scattering, Scattering, Plasma, Laser, law.invention, Ion, Physics::Plasma Physics, law, Electron temperature, Plasma diagnostics, Atomic physics, Instrumentation

Abstract

Imaging Thomson scattering measurements of collective ion-acoustic fluctuations have been utilized to determine ion temperature and density from laser produced counter-streaming asymmetric flows. Two foils are heated with 8 laser beams each, 500 J per beam, at the Omega Laser facility. Measurements are made 4 mm from the foil surface using a 60 J 2ω probe laser with a 200 ps pulse length. Measuring the electron density and temperature from the electron-plasma fluctuations constrains the fit of the multi-ion species, asymmetric flows theoretical form factor for the ion feature such that the ion temperatures, ion densities, and flow velocities for each plasma flow are determined.

Published

2014

42. Collisional effects in the ion Weibel instability for two counter-propagating plasma streams

Author

Frederico Fiuza, James Ross, Channing Huntington, H.-S. Park, and D. D. Ryutov

Subjects

Physics, Weibel instability, Two-stream instability, Filamentation, Shock (fluid dynamics), Physics::Plasma Physics, Electron temperature, Atomic physics, Condensed Matter Physics, Ion acoustic wave, Instability, Ion

Abstract

Experiments directed towards the study of the collisionless interaction between two counter-streaming plasma flows generated by high-power lasers are designed in such a way as to make collisions between the ions of the two flows negligibly rare. This is reached by making flow velocities v as high as possible and thereby exploiting the 1/v4 dependence of the Rutherford cross-section. At the same time, the plasma temperature of each flow may be relatively low so that collisional mean-free paths for the intra-stream particle collisions may be much smaller than the characteristic spatial scale of the unstable modes required for the shock formation. The corresponding effects are studied in this paper for the case of the ion Weibel (filamentation) instability. Dispersion relations for the case of strong intra-stream collisions are derived. It is shown that the growth-rates become significantly smaller than those stemming from a collisionless model. The underlying physics is mostly related to the increase of the electron stabilizing term. Additional effects are an increased “stiffness” of the collisional ion gas and the ion viscous dissipation. A parameter domain where collisions are important is identified.

Published

2014

43. Visualizing electromagnetic fields in laser-produced counter-streaming plasma experiments for collisionless shock laboratory astrophysics

Author

Gianluca Gregori, James Ross, Francesco Miniati, Alessandra Ravasio, Channing Huntington, C. Plechaty, Gennady Fiksel, M. Koenig, Po-Yu Chang, Yasuhiro Kuramitsu, Bruce Remington, A. Pelka, Dustin Froula, Carolyn Kuranz, H.-S. Park, Radu Presura, Hideaki Takabe, Siegfried Glenzer, Edison Liang, Brian Reville, Taichi Morita, Youichi Sakawa, Jena Meinecke, Nathan Kugland, Michael Grosskopf, Anatoly Spitkovsky, M. C. Levy, David Martinez, R. P. Drake, and Dmitri Ryutov

Subjects

Shock wave, Electromagnetic field, Physics, Plasma, Astrophysics, Condensed Matter Physics, 01 natural sciences, 010305 fluids & plasmas, Magnetic field, Physics::Plasma Physics, Physics::Space Physics, 0103 physical sciences, Astrophysical plasma, Plasma diagnostics, Magnetohydrodynamics, 010306 general physics, Inertial confinement fusion

Abstract

Collisionless shocks are often observed in fast-moving astrophysical plasmas, formed by non-classical viscosity that is believed to originate from collective electromagnetic fields driven by kinetic plasma instabilities. However, the development of small-scale plasma processes into large-scale structures, such as a collisionless shock, is not well understood. It is also unknown to what extent collisionless shocks contain macroscopic fields with a long coherence length. For these reasons, it is valuable to explore collisionless shock formation, including the growth and self-organization of fields, in laboratory plasmas. The experimental results presented here show at a glance with proton imaging how macroscopic fields can emerge from a system of supersonic counter-streaming plasmas produced at the OMEGA EP laser. Interpretation of these results, plans for additional measurements, and the difficulty of achieving truly collisionless conditions are discussed. Future experiments at the National Ignition Facility are expected to create fully formed collisionless shocks in plasmas with no pre-imposed magnetic field. © 2013 AIP Publishing LLC.

Published

2013

44. Design of experiments to observe radiation stabilized Rayleigh-Taylor instability growth at an embedded decelerating interface

Author

Bruce Remington, A. R. Miles, H.-S. Park, Shon Prisbrey, Channing Huntington, Harry Robey, C.C. Kuranz, and R. P. Drake

Subjects

Shock wave, Physics, Hohlraum, Radiative transfer, Mechanics, Rayleigh–Taylor instability, Atomic physics, Condensed Matter Physics, National Ignition Facility, Instability, Inertial confinement fusion, Shock (mechanics)

Abstract

Using a hohlraum produced thermal x-ray drive at the National Ignition Facility (NIF) to create pressure by material ablation, a shock exceeding 200 Mbar can be driven through a planar, solid-density target and into a lower-density foam material. The shock driven through the foam is strongly radiative, and this radiation significantly alters the dynamics of the system, including those of the Rayleigh-Taylor (RT) fluid instability at the interface between the two materials. We discuss here the design of experiments that can produce such radiative conditions. One will be able to compare the observed growth rates with an extensive body of hydrodynamic experiments performed previously. In this paper, we describe a set of 1D simulations performed to understand the mechanisms of stabilization in a strongly radiative Rayleigh-Taylor unstable system. Simulation results are used to calculate modified analytic RT growth rates which have been proposed in the literature. Calculations predict reduced RT spike growth as a result of increases in density gradient scale length and mass ablation from the unstable interface. This work has direct applicability to the observable features in upcoming NIF experiments.

Published

2011

45. Electronic measurement of microchannel plate pulse height distributions

Author

Eric Harding, Channing Huntington, E. J. Gamboa, and R. P. Drake

Subjects

Physics, Photon, Optical fiber, Microchannel, business.industry, Energy conversion efficiency, Plasma, Radiation, law.invention, Optics, law, Microchannel plate detector, Plasma diagnostics, business, Instrumentation

Abstract

Microchannel plates are a central component of the x-ray framing cameras used as analog imagers in many plasma experiment diagnostic systems. The microchannel plate serves as an amplifying element, increasing the electronic signal from incident radiation by factors of 10(3)-10(5), with a broad pulse-height distribution. Seeking to optimize the photon-to-electron conversion efficiency and noise distribution of x-ray cameras, we will characterize the pulse-height distribution of the electron output from a single microchannel plate. Replacing the framing camera's phosphor-coated fiber optic screen with a charge-collection plate and coupling to a low-noise multichannel analyzer, we quantified the distribution in the total charge generated per photon event. The electronically measured pulse height distribution is used to estimate the signal-to-noise ratio of radiographic images from framing cameras.

Published

2010

46. Performance of Au transmission photocathode on a microchannel plate detector

Author

G.K. Rathore, Eric Harding, A. J. Visco, R. P. Drake, M. E. Lowenstern, and Channing Huntington

Subjects

Physics, Photomultiplier, Microchannel, Optics, business.industry, Electric field, Microchannel plate detector, Electron, business, Instrumentation, Photocathode, Particle detector, Voltage

Abstract

X-ray framing cameras, employing microchannel plates (MCPs) for detection and signal amplification, play a key role in research in high-energy-density physics. These instruments convert radiographic x-rays into electrons produced by plasma during such experiments into electrons that are amplified in the channels and then detected by a phosphor material. The separation of detection from signal amplification offers potential improvements in sensitivity and noise properties. We have implemented a suspended Au transmission photocathode (160 A thick) on a MCP and are evaluating it using a 1.5 keV Al K alpha x-ray source. We find an approximately twofold increase in the ratio of detected events to incident photons when the photocathode-to-MCP voltage difference is sufficiently large. Our calculations indicate that this increase is probably caused by a combination of signal produced by the photocathode and an increase in the efficiency of detection of x-rays that reach the MCP surface through modification of the local electric field.

Published

2008