Publications

High Energy Density Physics

Coverdale, Christine A.; Jones, Brent M.; Ampleford, David A.; Hansen, Stephanie B.

Abstract not provided.

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

Abstract not provided.

Ampleford, David A.; Jennings, Christopher A.; Hansen, Stephanie B.; Cuneo, M.E.; Jones, Brent M.; Nielsen, D.S.; Coverdale, Christine A.

Abstract not provided.

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.

Abstract not provided.

Ampleford, David A.; Jennings, Christopher A.; Jones, Brent M.; Hansen, Stephanie B.; Cuneo, M.E.; Coverdale, Christine A.; Jones, Michael J.

Abstract not provided.

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.

Abstract not provided.

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

Abstract not provided.

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.

Abstract not provided.

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

Abstract not provided.

Ampleford, David A.; Jennings, Christopher A.; Jones, Brent M.; Hansen, Stephanie B.

Abstract not provided.

Ampleford, David A.; Jennings, Christopher A.; Hansen, Stephanie B.; Cuneo, M.E.

Abstract not provided.

Cuneo, M.E.; Sinars, Daniel S.; Nakhleh, Charles N.; Slutz, Stephen A.; Vesey, Roger A.; Hansen, Stephanie B.; Stygar, William A.; Matzen, M.K.

Abstract not provided.

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.

Abstract not provided.

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.

Canadian Journal of Physics

Hansen, Stephanie B.

Abstract not provided.

Hansen, Stephanie B.

Abstract not provided.

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.

Sinars, Daniel S.; McBride, Ryan D.; Wenger, D.F.; Cuneo, M.E.; Yu, Edmund Y.; Harding, Eric H.; Hansen, Stephanie B.; Ampleford, David A.; Jennings, Christopher A.

This final report for Project 117863 summarizes progress made toward understanding how X-pinch load designs scale to high currents. The X-pinch load geometry was conceived in 1982 as a method to study the formation and properties of bright x-ray spots in z-pinch plasmas. X-pinch plasmas driven by 0.2 MA currents were found to have source sizes of 1 micron, temperatures >1 keV, lifetimes of 10-100 ps, and densities >0.1 times solid density. These conditions are believed to result from the direct magnetic compression of matter. Physical models that capture the behavior of 0.2 MA X pinches predict more extreme parameters at currents >1 MA. This project developed load designs for up to 6 MA on the SATURN facility and attempted to measure the resulting plasma parameters. Source sizes of 5-8 microns were observed in some cases along with evidence for high temperatures (several keV) and short time durations (<500 ps).

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

Abstract not provided.

Ampleford, David A.; Hansen, Stephanie B.; Cuneo, M.E.; Jennings, Christopher A.; Jones, Brent M.; Coverdale, Christine A.; Nash, Thomas J.; Jones, Scott C.; Jones, Michael J.; Stygar, William A.; Savage, Mark E.

Abstract not provided.

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

Large diameter nested wire array z-pinches imploded on the Z-generator at Sandia National Laboratories have been used extensively to generate high intensity K-shell radiation. Large initial radii are required to obtain the high implosion velocities needed to efficiently radiate in the K-shell. This necessitates low wire numbers and large inter-wire gaps which introduce large azimuthal non-uniformities. Furthermore, the development of magneto-Rayleigh-Taylor instabilities during the implosion are known to generate large axial non-uniformity These effects motivate the complete, full circumference 3-dimensional modeling of these systems. Such high velocity implosions also generate large voltages, which increase current losses in the power feed and limit the current delivery to these loads. Accurate representation of the generator coupling is therefore required to reliably represent the energy delivered to, and the power radiated from these sources. We present 3D-resistive MHD calculations of the implosion and stagnation of a variety of large diameter stainless steel wire arrays (hv {approx} 6.7 keV), imploded on the Z-generator both before and after its refurbishment. Use of a tabulated K-shell emission model allows us to compare total and K-shell radiated powers to available experimental measurements. Further comparison to electrical voltage and current measurements allows us to accurately assess the power delivered to these loads. These data allow us to begin to constrain and validate our 3D MHD calculations, providing insight into ways in which these sources may be further optimized.

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

Large diameter (50-70 mm) wire array z pinches are fielded on the refurbished Z machine to generate 1-10 keV K-shell x-ray radiation. Imploding with velocities approaching 100 cm/{micro}s, these loads create large dL/dt which generates a high voltage, stresses the convolute, and leads to current loss. High velocities are required to reach the few-keV electron temperatures required to strip moderate-atomic-number plasmas to the K shell, thus there is an inherent trade-off between achieving high velocity and stressing the pulsed power driver via the large dL/dt.Here, we present experiments in which the length of stagnated Cu and stainless steel z pinches was varied from 12-24 mm. The motivation in reducing the pinch height is to lower the final inductance and improve coupling to the generator. Shortening a Cu pinch from 20 to 12 mm by angling the anode glide plane reduced the final L and dL/dt, enhancing the feed current by 1.4 MA, nearly doubling the K-shell power per unit length, and increasing the net K-shell yield by 20%. X-ray spectroscopy is employed to assess differences in plasma conditions between the loads. Lengthening the pinch could lead to yield enhancements by increasing the mass participating in the implosion, provided the increased inductance is not overly detrimental to the current coupling. In addition to the experimental results, these scenarios are studied via thin-shell 0D and also magneto-hydrodynamic modeling with a coupled driver circuit model.

Hansen, Stephanie B.

Abstract not provided.

High Energy Density Physics

Hansen, Stephanie B.

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.