Publications

Proposed for publication in 5th Special Issue of the IEEE Transactions on Plasma Science Z-Pinch Plasmas.

Cuneo, M.E.; Mazarakis, Michael G.; Lamppa, Derek C.; Kaye, Ronald J.; Nakhleh, Charles N.; Bailey, James E.; Hansen, Stephanie B.; McBride, Ryan D.; Herrmann, Mark H.; Lopez, A.; Peterson, Kyle J.; Ampleford, David A.; Jones, Michael J.; Savage, Mark E.; Jennings, Christopher A.; Martin, Matthew; Slutz, Stephen A.; Lemke, Raymond W.; Christenson, Peggy J.; Sweeney, Mary A.; Jones, Brent M.; Yu, Edmund Y.; McPherson, Leroy A.; Harding, Eric H.; Knapp, Patrick K.; Gomez, Matthew R.; Awe, Thomas J.; Stygar, William A.; Leeper, Ramon J.; Ruiz, Carlos L.; Chandler, Gordon A.; Mckenney, John M.; Owen, Albert C.; McKee, George R.; Matzen, M.K.; Leifeste, Gordon T.; Atherton, B.W.; Vesey, Roger A.; Smith, Ian C.; Geissel, Matthias G.; Rambo, Patrick K.; Sinars, Daniel S.; Sefkow, Adam B.; Rovang, Dean C.; Rochau, G.A.

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Bailey, James E.

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Bailey, James E.; Loisel, Guillaume P.; Rochau, G.A.; Dunham, Gregory S.; Ball, Christopher R.

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Ao, Tommy A.; Harding, Eric H.; Bailey, James E.; Sinars, Daniel S.; Desjarlais, Michael P.; Hansen, Stephanie B.; Lemke, Raymond W.; Smith, Ian C.

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Bailey, James E.

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Cuneo, M.E.; Jones, Michael J.; Edens, Aaron E.; Lopez, Mike R.; McBride, Ryan D.; Rochau, G.A.; Jones, Brent M.; Ampleford, David A.; Sinars, Daniel S.; Bailey, James E.; Stygar, William A.; Savage, Mark E.

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Ao, Tommy A.; Bailey, James E.; Hansen, Stephanie B.; Desjarlais, Michael P.; Mix, L.P.; Smith, Ian C.; Sinars, Daniel S.

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Bailey, James E.

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Cuneo, M.E.; Savage, Mark E.; Jones, Michael J.; Edens, Aaron E.; Lopez, Mike R.; Gomez, Matthew R.; McBride, Ryan D.; Rochau, G.A.; Jones, Brent M.; Ampleford, David A.; Sinars, Daniel S.; Bailey, James E.; Stygar, William A.

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Cuneo, M.E.; Jones, Michael J.; Edens, Aaron E.; Lopez, Mike R.; McBride, Ryan D.; Rochau, G.A.; Jones, Brent M.; Ampleford, David A.; Sinars, Daniel S.; Bailey, James E.; Stygar, William A.; Savage, Mark E.

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Ao, Tommy A.; Wenger, D.F.; Bailey, James E.; Desjarlais, Michael P.; Hansen, Stephanie B.; Knudson, Marcus D.; Lemke, Raymond W.; Mix, L.P.; Sinars, Daniel S.; Smith, Ian C.

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Cuneo, M.E.; Jones, Michael J.; Edens, Aaron E.; Lopez, Mike R.; McBride, Ryan D.; Rochau, G.A.; Jones, Brent M.; Ampleford, David A.; Sinars, Daniel S.; Bailey, James E.; Stygar, William A.; Savage, Mark E.

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Rochau, G.A.; Coverdale, Christine A.; Hansen, Stephanie B.; Yu, Edmund Y.; Ampleford, David A.; Lake, Patrick W.; Dunham, Gregory S.; Cuneo, M.E.; Jones, Brent M.; Jennings, Christopher A.; Bailey, James E.

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Hansen, Stephanie B.; Desjarlais, Michael P.; Bailey, James E.; Harding, Eric H.; Ao, Tommy A.

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Ao, Tommy A.; Wenger, D.F.; Bailey, James E.; Desjarlais, Michael P.; Hansen, Stephanie B.; Knudson, Marcus D.; Lemke, Raymond W.; Mix, L.P.; Sinars, Daniel S.; Smith, Ian C.

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High Energy Density Physics

Hansen, Stephanie B.; Jones, Brent M.; Ampleford, David A.; Coverdale, Christine A.; Jennings, Christopher A.; Cuneo, M.E.; Rochau, G.A.; Bailey, James E.

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Rochau, G.A.; Bailey, James E.; Coverdale, Christine A.; Ampleford, David A.; Cuneo, M.E.; Jones, Brent M.; Jennings, Christopher A.; Yu, Edmund Y.; Hansen, Stephanie B.

Fast z-pinches provide intense 1-10 keV photon energy radiation sources. Here, we analyze time-, space-, and spectrally-resolved {approx}2 keV K-shell emissions from Al (5% Mg) wire array implosions on Sandia's Z machine pulsed power driver. The stagnating plasma is modeled as three separate radial zones, and collisional-radiative modeling with radiation transport calculations are used to constrain the temperatures and densities in these regions, accounting for K-shell line opacity and Doppler effects. We discuss plasma conditions and dynamics at the onset of stagnation, and compare inferences from the atomic modeling to three-dimensional magneto-hydrodynamic simulations.

Bailey, James E.

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Bailey, James E.

The new generation of z-pinch, laser, and XFEL facilities opens the possibility to produce astrophysically-relevant laboratory plasmas with energy densities beyond what was previously possible. Furthermore, macroscopic plasmas with uniform conditions can now be created, enabling more accurate determination of the material properties. This presentation will provide an overview of our research at the Z facility investigating stellar interior opacities, AGN warm-absorber photoionized plasmas, and white dwarf photospheres. Atomic physics in plasmas heavily influence these topics. Stellar opacities are an essential ingredient of stellar models and they affect what we know about the structure and evolution of stars. Opacity models have become highly sophisticated, but laboratory tests have not been done at the conditions existing inside stars. Our research is presently focused on measuring Fe at conditions relevant to the base of the solar convection zone, where the electron temperature and density are believed to be 190 eV and 9 x 10{sup 22} e/cc, respectively. The second project is aimed at testing atomic kinetics models for photoionized plasmas. Photoionization is an important process in many astrophysical plasmas and the spectral signatures are routinely used to infer astrophysical object's characteristics. However, the spectral synthesis models at the heart of these interpretations have been the subject of very limited experimental tests. Our current research examines photoionization of neon plasma subjected to radiation flux similar to the warm absorber that surrounds active galactic nuclei. The third project is a recent initiative aimed at producing a white dwarf photosphere in the laboratory. Emergent spectra from the photosphere are used to infer the star's effective temperature and surface gravity. The results depend on knowledge of H, He, and C spectral line profiles under conditions where complex physics such as quasi-molecule formation may be important. These profiles have been studied in past experiments, but puzzles emerging from recent white dwarf analysis have raised questions about the accuracy of the line profile models. Proof-of-principle data has been acquired that indicates radiation-heated quiescent plasmas can be produced with {approx} 1 eV temperature and 10{sup 17}-10{sup 19} e/cc densities, in an {approx} 20cm{sup 3} volume. Such plasmas would provide a valuable platform for investigating numerous line profile questions.

Hansen, Stephanie B.; Jones, Brent M.; Ampleford, David A.; Bailey, James E.; Rochau, G.A.; Coverdale, Christine A.; Jennings, Christopher A.; Cuneo, M.E.

Spatially and temporally resolved X-ray emission lines contain information about temperatures, densities, velocities, and the gradients in a plasma. Extracting this information from optically thick lines emitted from complex ions in dynamic, three-dimensional, non-LTE plasmas requires self-consistent accounting for both non-LTE atomic physics and non-local radiative transfer. We present a brief description of a hybrid-structure spectroscopic atomic model coupled to an iterative tabular on-the-spot treatment of radiative transfer that can be applied to plasmas of arbitrary material composition, conditions, and geometries. The effects of Doppler line shifts on the self-consistent radiative transfer within the plasma and the emergent emission and absorption spectra are included in the model. Sample calculations for a two-level atom in a uniform cylindrical plasma are given, showing reasonable agreement with more sophisticated transport models and illustrating the potential complexity - or richness - of radially resolved emission lines from an imploding cylindrical plasma. Also presented is a comparison of modeled L- and K-shell spectra to temporally and radially resolved emission data from a Cu:Ni plasma. Finally, some shortcomings of the model and possible paths for improvement are discussed.

Bailey, James E.

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Bailey, James E.

Experiments in terrestrial laboratories can be used to evaluate the physical models that interpret astronomical observations. The properties of matter in astrophysical objects are essential components of these models, but terrestrial laboratories struggle to reproduce the extreme conditions that often exist. Megajoule-class DOE/NNSA facilities such as the National Ignition Facility and Z can create unprecedented amounts of matter at extreme conditions, providing new capabilities to test astrophysical models with high accuracy. Experiments at these large facilities are challenging, and access is very competitive. However, the cylindrically-symmetric Z source emits radiation in all directions, enabling multiple physics experiments to be driven with a single Z discharge. This helps ameliorate access limitations. This article describes research efforts under way at Sandia National Laboratories Z facility investigating radiation transport through stellar interior matter, population kinetics of atoms exposed to the intense radiation emitted by accretion powered objects, and spectral line formation in white dwarf (WD) photospheres. Opacity quantifies the absorption of radiation by matter and strongly influences stellar structure and evolution, since radiation dominates energy transport deep inside stars. Opacity models have become highly sophisticated, but laboratory tests at the conditions existing inside stars have not been possible - until now. Z research is presently focused on measuring iron absorption at conditions relevant to the base of the solar convection zone, where the electron temperature and density are 190 eV and 9 x 10{sup 22} e/cc, respectively. Creating these conditions in a sample that is sufficiently large, long-lived, and uniform is extraordinarily challenging. A source of radiation that streams through the relatively-large samples can produce volumetric heating and thus, uniform conditions, but to achieve high temperatures a strong source is required. Z dynamic hohlraums provide such a megajoule-class source. Initial Z experiments measured transmission through iron samples ionized to the same charge states that exist at the solar convection zone base. The resulting data made it possible to test challenging aspects of the opacity calculations such as the ionization balance and the completeness and accuracy of the atomic energy level description. However, the density was too low to provide a definitive test of the physics at the solar convection zone base. Recent experiments have reached higher densities, and opacity model tests for stellar interiors now appear within reach. Accretion powered objects, including active galactic nuclei, x-ray binaries, and black hole accretion disks, are the most luminous objects in the universe. Astrophysical models for these objects rely largely on comparing spectroscopic predictions with observations. A dilemma arises because the spectra originate from plasmas that are bathed in the enormous photon flux from the accretion disk and photoionization dominates the atomic ionization and energy level populations. Thus, constraining astrophysical models depends on accurate atomic models for photoionized plasmas. Unfortunately, to date the ionization in almost all laboratory experiments is collision-dominated and very few tests of photoionized plasma atomic kinetics exist. Megajoule class high-energy-density facilities can help because they generate higher x-ray fluence over larger spatial scales and longer times. Expanded iron foils and pre-filled neon gas cells have been used in experiments at Z to study photoionized atomic kinetics in two elements commonly observed in astrophysical objects. In these experiments, low density samples are exposed to a measured intense x-ray spectrum, emergent emission or absorption spectra are recorded, and the results are compared to predictions made with spectral synthesis codes used by astrophysicists. Initial experiments focused on testing models used to interpret spectra from the 'warm absorber,' a plasma observed in the vicinity of some active galactic nuclei. In future experiments, spectra from plasmas exposed to higher radiation intensities will be measured, possibly leading to improved understanding of the plasma in the immediate vicinity of the accretion disk. WDs are the oldest stars and can serve as cosmic clocks, since the universe must be at least as old as the objects within it. Astrophysicists determine WD ages using stellar models combined with effective temperature (T{sub eff}) and mass inferred from spectral observations of WD photospheres. Many line profiles in the observed spectra are dominated by Stark broadening, a process sensitive to the photosphere density and related to the total mass through the stellar model. Accurate Stark broadening theory is, therefore, critical to the precise determination of the WD properties and the inferred ages.

Review of Scientific Instruments

Nash, Thomas J.; Rochau, G.A.; Bailey, James E.

We are attempting to measure the transmission of iron on Z at plasma temperatures and densities relevant to the solar radiation and convection zone boundary. The opacity data published by us to date has been taken at an electron density about a factor of 10 below the 9× 1022/cm3 electron density of this boundary. We present results of two-dimensional (2D) simulations of the heating and expansion of an opacity sample driven by the dynamic Hohlraum radiation source on Z. The aim of the simulations is to design foil samples that provide opacity data at increased density. The inputs or source terms for the simulations are spatially and temporally varying radiation temperatures with a Lambertian angular distribution. These temperature profiles were inferred on Z with on-axis time-resolved pinhole cameras, x-ray diodes, and bolometers. A typical sample is 0.3 μm of magnesium and 0.078 μm of iron sandwiched between 10 μm layers of plastic. The 2D LASNEX simulations indicate that to increase the density of the sample one should increase the thickness of the plastic backing. © 2010 American Institute of Physics.

Bailey, James E.

Abstract not provided.

Jennings, Christopher A.; Cuneo, M.E.; Jones, Brent M.; Yu, Edmund Y.; Ampleford, David A.; Hansen, Stephanie B.; Ruiz, Carlos L.; Rochau, G.A.; Bailey, James E.; Coverdale, Christine A.

Abstract not provided.