Your search keyword '"Hansen, S. B."' showing total 20 results

1. Radiatively Cooled Magnetic Reconnection Experiments Driven by Pulsed Power

Author

Datta, R, Chandler, K, Myers, C E, Chittenden, J P, Crilly, A J, Aragon, C, Ampleford, D J, Banasek, J T, Edens, A, Fox, W R, Hansen, S B, Harding, E C, Jennings, C A, Ji, H, Kuranz, C C, Lebedev, S V, Looker, Q, Patel, S G, Porwitzky, A J, Shipley, G A, Uzdensky, D A, Yager-Elorriaga, D A, and Hare, J D

Subjects

Physics - Plasma Physics

Abstract

We present evidence for strong radiative cooling in a pulsed-power-driven magnetic reconnection experiment. Two aluminum exploding wire arrays, driven by a 20 MA peak current, 300 ns rise time pulse from the Z machine (Sandia National Laboratories), generate strongly-driven plasma flows ($M_A \approx 7$) with anti-parallel magnetic fields, which form a reconnection layer ($S_L \approx 120$) at the mid-plane. The net cooling rate far exceeds the Alfv\'enic transit rate ($\tau_{\text{cool}}^{-1}/\tau_{\text{A}}^{-1} > 100$), leading to strong cooling of the reconnection layer. We determine the advected magnetic field and flow velocity using inductive probes positioned in the inflow to the layer, and inflow ion density and temperature from analysis of visible emission spectroscopy. A sharp decrease in X-ray emission from the reconnection layer, measured using filtered diodes and time-gated X-ray imaging, provides evidence for strong cooling of the reconnection layer after its initial formation. X-ray images also show localized hotspots, regions of strong X-ray emission, with velocities comparable to the expected outflow velocity from the reconnection layer. These hotspots are consistent with plasmoids observed in 3D radiative resistive magnetohydrodynamic simulations of the experiment. X-ray spectroscopy further indicates that the hotspots have a temperature (170 eV) much higher than the bulk layer ($\leq$ 75 eV) and inflow temperatures (about 2 eV), and that these hotspots generate the majority of the high-energy (> 1 keV) emission.

Published

2024

2. Plasmoid formation and strong radiative cooling in a driven magnetic reconnection experiment

Author

Datta, R., Chandler, K., Myers, C. E., Chittenden, J. P., Crilly, A. J., Aragon, C., Ampleford, D. J., Banasek, J. T., Edens, A., Fox, W. R., Hansen, S. B., Harding, E. C., Jennings, C. A., Ji, H., Kuranz, C. C., Lebedev, S. V., Looker, Q., Patel, S. G., Porwitzky, A., Shipley, G. A., Uzdensky, D. A., Yager-Elorriaga, D. A., and Hare, J. D.

Subjects

Physics - Plasma Physics

Abstract

We present results from the first experimental study of strongly radiatively-cooled magnetic reconnection. Two exploding aluminum wire arrays, driven simultaneously by the Z machine ($I_{max} = 20 \, \text{MA}$, $t_{\text{rise}} = 300 \, \text{ns}$), generate a radiatively-cooled reconnection layer ($S_L \approx 120$) in which the total cooling rate exceeds the hydrodynamic transit rate ($\tau_{\text{hydro}}/\tau_{\text{cool}} > 100$). Measurements of X-ray emission from the reconnection layer using a filtered diode ($>1$ keV) show a narrow (50 ns FWHM) burst of emission at 220 ns after current start, consistent with the formation and subsequent rapid cooling of the reconnection layer. Time-gated X-ray images of the reconnection layer show fast-moving (up to 50 km/s) hotspots inside the layer, consistent with the presence of plasmoids observed in 3D resistive magnetohydrodynamic simulations. X-ray spectroscopy shows that these hotspots generate the majority of Al K-shell emission (at around 1.6 keV) prior to the onset of cooling, and exhibit temperatures of 170 eV, much greater than the temperature of the plasma inflows and the rest of the reconnection layer.

Published

2024

3. Thermal transport in warm dense matter revealed by refraction-enhanced x-ray radiography with a deep-neural-network analysis

Author

Jiang, S., Landen, O. L., Whitley, H. D., Hamel, S., London, R., Clark, D. S., Sterne, P., Hansen, S. B., Hu, S. X., Collins, G. W., and Ping, Y.

Published

2023

4. Radiatively cooled magnetic reconnection experiments driven by pulsed power

Author

Datta, R., primary, Chandler, K., additional, Myers, C. E., additional, Chittenden, J. P., additional, Crilly, A. J., additional, Aragon, C., additional, Ampleford, D. J., additional, Banasek, J. T., additional, Edens, A., additional, Fox, W. R., additional, Hansen, S. B., additional, Harding, E. C., additional, Jennings, C. A., additional, Ji, H., additional, Kuranz, C. C., additional, Lebedev, S. V., additional, Looker, Q., additional, Patel, S. G., additional, Porwitzky, A., additional, Shipley, G. A., additional, Uzdensky, D. A., additional, Yager-Elorriaga, D. A., additional, and Hare, J. D., additional

Published

2024

5. Plasmoid Formation and Strong Radiative Cooling in a Driven Magnetic Reconnection Experiment

Author

Datta, R., primary, Chandler, K., additional, Myers, C. E., additional, Chittenden, J. P., additional, Crilly, A. J., additional, Aragon, C., additional, Ampleford, D. J., additional, Banasek, J. T., additional, Edens, A., additional, Fox, W. R., additional, Hansen, S. B., additional, Harding, E. C., additional, Jennings, C. A., additional, Ji, H., additional, Kuranz, C. C., additional, Lebedev, S. V., additional, Looker, Q., additional, Patel, S. G., additional, Porwitzky, A., additional, Shipley, G. A., additional, Uzdensky, D. A., additional, Yager-Elorriaga, D. A., additional, and Hare, J. D., additional

Published

2024

6. Phase retrieval for refraction-enhanced x-ray radiography using a deep neural network.

Author

Jiang, S., Landen, O. L., Whitley, H. D., Hamel, S., London, R. A., Sterne, P., Hansen, S. B., Hu, S. X., Collins, G. W., and Ping, Y.

Subjects

ARTIFICIAL neural networks, RADIOGRAPHY, X-ray absorption, X-rays, ALGORITHMS

Abstract

X-ray refraction-enhanced radiography (RER) or phase contrast imaging is widely used to study internal discontinuities within materials. The resulting radiograph captures both the decrease in intensity caused by material absorption along the x-ray path, as well as the phase shift, which is highly sensitive to gradients in density. A significant challenge lies in effectively analyzing the radiographs to decouple the intensity and phase information and accurately ascertain the density profile. Conventional algorithms often yield ambiguous and unrealistic results due to difficulties in including physical constraints and other relevant information. We have developed an algorithm that uses a deep neural network to address these issues and applied it to extract the detailed density profile from an experimental RER. To generalize the applicability of our algorithm, we have developed a technique that quantitatively evaluates the complexity of the phase retrieval process based on the characteristics of the sample and the configuration of the experiment. Accordingly, this evaluation aids in the selection of the neural network architecture for each specific case. Beyond RER, the model has potential applications for other diagnostics where phase retrieval analysis is required. [ABSTRACT FROM AUTHOR]

Published

2024

7. Development of a high performance MagLIF target platform using high aspect ratio coated liners and low-mix laser preheat.

Author

Harvey-Thompson, A. J., Geissel, M. E., Lewis, W. E., Yager-Elorriaga, D. A., Weis, M. R., Jennings, C. A., Fein, J. R., Ampleford, D. J., Gomez, M. R., Harding, E. C., Hansen, S. B., Bliss, D. E., Chandler, G. A., Dunham, G. S., Field, E. S., Galloway, B. R., Glinsky, M., Hahn, K. D., Knapp, P. F., and Lamppa, D. C.

Abstract

We report on a series of Magnetized Liner Inertial Fusion (MagLIF) experiments conducted on the Z pulsed power facility that utilized high aspect ratio (ratio of outer radius to wall thickness) liners with dielectric coatings and low-mix laser preheat configurations. The liners consisted of an aspect ratio of 10.6 beryllium tube coated with 75 μm of epoxy on the outside that have been shown to maintain a better implosion stability than uncoated beryllium and have demonstrated consistent stagnation performances in previous experiments [Ampleford et al., Phys. Plasmas 31, 022703 (2024)]. Two-dimensional HYDRA simulations were used to design three different "co-injection" laser configurations, whereby a second laser is used to provide an early prepulse before the main pulse, to reduce LEH foil mix while increasing the fuel density and coupled energy. The laser preheat energy for each configuration was constrained using dedicated laser experiments before being applied to the integrated MagLIF experiments on Z. The DD neutron yield for experiments using co-injection preheat configurations is found to increase with the specific preheat energy in line with simulations. The highest neutron yield achieved in this study of 1.1 × 1013 matches the highest reported in a MagLIF experiment to date and is a factor 3.5 times higher than similar experiments using preheat with no phase plate smoothing. We attempt to assess the effects of mix and morphology to explain the improved performance; however, neither factor is found to be conclusive within the uncertainty of the measurements. [ABSTRACT FROM AUTHOR]

Published

2024

8. Controlling morphology and improving reproducibility of magnetized liner inertial fusion experiments

Author

Ampleford, D. J., primary, Yager-Elorriaga, D. A., additional, Jennings, C. A., additional, Harding, E. C., additional, Gomez, M. R., additional, Harvey-Thompson, A. J., additional, Awe, T. J., additional, Chandler, G. A., additional, Dunham, G. S., additional, Geissel, M., additional, Hahn, K. D., additional, Hansen, S. B., additional, Knapp, P. F., additional, Lamppa, D. C., additional, Lewis, W. E., additional, Lucero, L., additional, Mangan, M., additional, Paguio, R., additional, Perea, L., additional, Robertson, G. A., additional, Ruiz, C. L., additional, Ruiz, D. E., additional, Schmit, P. F., additional, Slutz, S. A., additional, Smith, G. E., additional, Smith, I. C., additional, Speas, C. S., additional, Webb, T. J., additional, Weis, M. R., additional, Whittemore, K., additional, Yu, E. P., additional, McBride, R. D., additional, Peterson, K. J., additional, Jones, B. M., additional, Rochau, G. A., additional, and Sinars, D. B., additional

Published

2024

9. A generalized approach to x-ray data modeling for high-energy-density plasma experiments

Author

Nagayama, T., primary, Schaeuble, M. A., additional, Fein, J. R., additional, Loisel, G. P., additional, Wu, M., additional, Mayes, D. C., additional, Hansen, S. B., additional, Knapp, P. F., additional, Webb, T. J., additional, Schwarz, J., additional, and Vesey, R. A., additional

Published

2023

10. Demonstration of improved laser preheat with a cryogenically cooled magnetized liner inertial fusion platform

Author

Harvey-Thompson, A. J., primary, Geissel, M., additional, Crabtree, J. A., additional, Weis, M. R., additional, Gomez, M. R., additional, Fein, J. R., additional, Lewis, W. E., additional, Ampleford, D. J., additional, Awe, T. J., additional, Chandler, G. A., additional, Galloway, B. R., additional, Hansen, S. B., additional, Hanson, J., additional, Harding, E. C., additional, Jennings, C. A., additional, Kimmel, M., additional, Knapp, P. F., additional, Mangan, M. A., additional, Maurer, A., additional, Paguio, R. R., additional, Perea, L., additional, Peterson, K. J., additional, Porter, J. L., additional, Rambo, P. K., additional, Robertson, G. K., additional, Rochau, G. A., additional, Ruiz, D. E., additional, Shores, J. E., additional, Slutz, S. A., additional, Smith, G. E., additional, Smith, I. C., additional, Speas, C. S., additional, Yager-Elorriaga, D. A., additional, and York, A., additional

Published

2023

11. Experimental demonstration of >20 kJ laser energy coupling in 1-cm hydrocarbon-filled gas pipe targets via inverse Bremsstrahlung absorption with applications to MagLIF

Author

Pollock, B. B., primary, Goyon, C., additional, Sefkow, A. B., additional, Glinsky, M. E., additional, Peterson, K. J., additional, Weis, M. R., additional, Carroll, E. G., additional, Fry, J., additional, Piston, K., additional, Harvey-Thompson, A. J., additional, Hansen, S. B., additional, Beckwith, K., additional, Ampleford, D. J., additional, Tubman, E. R., additional, Strozzi, D. J., additional, Ross, J. S., additional, and Moody, J. D., additional

Published

2023

12. Improving dynamic collision frequencies: Impacts on dynamic structure factors and stopping powers in warm dense matter

Author

Hentschel, T. W., Kononov, A., Olmstead, A., Cangi, A., Baczewski, A. D., and Hansen, S. B.

Subjects

Matter under extreme conditions, X-ray Thomson scattering, Average-atom models, Density functional theory, Time-dependent density functional theory, Collision frequencies, High-energy density science, Warm dense matter

Abstract

Simulations and diagnostics of high-energy-density plasmas and warm dense matter rely on models of material response properties, both static and dynamic (frequency-dependent). Here, we systematically investigate variations in dynamic electron–ion collision frequencies ν(ω) in warm dense matter using data from a self-consistent-field average-atom model. We show that including the full quantum density of states, strong collisions, and inelastic collisions lead to significant changes in ν(ω) ⁠. These changes result in red shifts and broadening of the plasmon peak in the dynamic structure factor, an effect observable in x-ray Thomson scattering spectra, and modify stopping powers around the Bragg peak. These changes improve the agreement of computationally efficient average-atom models with first-principles time-dependent density functional theory in warm dense aluminum, carbon, and deuterium.

Published

2023

13. Self-consistent and detailed opacities from a non-equilibrium average-atom model.

Author

Hansen, S. B.

Subjects

*LOCAL thermodynamic equilibrium, *EQUATIONS of state, *ION recombination, *DENSITY functional theory, *PLASMA density, *TRP channels, *AUGER effect

Abstract

Modern density functional theory (DFT) is a powerful tool for accurately predicting self-consistent material properties such as equations of state, transport coefficients and opacities in high energy density plasmas, but it is generally restricted to conditions of local thermodynamic equilibrium (LTE) and produces only averaged electronic states instead of detailed configurations. We propose a simple modification to the bound-state occupation factor of a DFT-based average-atom model that captures essential non-LTE effects in plasmas—including autoionization and dielectronic recombination—thus extending DFT-based models to new regimes. We then expand the self-consistent electronic orbitals of the non-LTE DFT-AA model to generate multi-configuration electronic structure and detailed opacity spectra. This article is part of the theme issue 'Dynamic and transient processes in warm dense matter'. [ABSTRACT FROM AUTHOR]

Published

2023

14. Homogeneous, Micron-Scale High-Energy-Density Matter Generated by Relativistic Laser-Solid Interactions

Author

Beier, N. F., primary, Allison, H., additional, Efthimion, P., additional, Flippo, K. A., additional, Gao, L., additional, Hansen, S. B., additional, Hill, K., additional, Hollinger, R., additional, Logantha, M., additional, Musthafa, Y., additional, Nedbailo, R., additional, Senthilkumaran, V., additional, Shepherd, R., additional, Shlyaptsev, V. N., additional, Song, H., additional, Wang, S., additional, Dollar, F., additional, Rocca, J. J., additional, and Hussein, A. E., additional

Published

2022

15. First-principles derivation and properties of density-functional average-atom models

Author

(0000-0002-4878-3521) Callow, T. J., Hansen, S. B., (0000-0003-0139-258X) Kraisler, E., (0000-0001-9162-262X) Cangi, A., (0000-0002-4878-3521) Callow, T. J., Hansen, S. B., (0000-0003-0139-258X) Kraisler, E., and (0000-0001-9162-262X) Cangi, A.

Abstract

Finite-temperature Kohn--Sham density-functional theory (KS-DFT) is a widely-used method in warm dense matter (WDM) simulations and diagnostics. Unfortunately, full KS-DFT-molecular dynamics models scale unfavourably with temperature and there remains uncertainty regarding the performance of existing approximate exchange-correlation (XC) functionals under WDM conditions. Of particular concern is the expected explicit dependence of the XC functional on temperature, which is absent from most approximations. Average-atom (AA) models, which significantly reduce the computational cost of KS-DFT calculations, have therefore become an integral part of WDM modelling. In this paper, we present a derivation of a first-principles AA model from the fully-interacting many-body Hamiltonian, carefully analysing the assumptions made and terms neglected in this reduction. We explore the impact of different choices within this model -- such as boundary conditions and XC functionals -- on common properties in WDM, for example equation-of-state data, ionization degree and the behaviour of the frontier energy levels. Furthermore, drawing upon insights from ground-state KS-DFT, we discuss the likely sources of error in KS-AA models and possible strategies for mitigating such errors.

Published

2022

16. Improving Predictive Capability in REHEDS Simulations with Fast, Accurate, and Consistent Non-Equilibrium Material Properties

Author

Hansen, S. B., Baczewski, A. D., Gomez, T., Hentschel, T. W., Jennings, C. A., Kononov, A., Nagayama, T., Adler, K., (0000-0001-9162-262X) Cangi, A., Cochrane, K., Robinson, B., Schleife, A., Hansen, S. B., Baczewski, A. D., Gomez, T., Hentschel, T. W., Jennings, C. A., Kononov, A., Nagayama, T., Adler, K., (0000-0001-9162-262X) Cangi, A., Cochrane, K., Robinson, B., and Schleife, A.

Abstract

Predictive design of REHEDS experiments with radiation-hydrodynamic simulations requires knowledge of material properties (e.g. equations of state (EOS), transport coefficients, and radiation physics). Interpreting experimental results requires accurate models of diagnostic observables (e.g. detailed emission, absorption, and scattering spectra). In conditions of Local Thermodynamic Equilibrium (LTE), these material properties and observables can be pre-computed with relatively high accuracy and subsequently tabulated on simple temperature-density grids for fast look-up by simulations. When radiation and electron temperatures fall out of equilibrium, however, non-LTE effects can profoundly change material properties and diagnostic signatures. Accurately and efficiently incorporating these non-LTE effects has been a longstanding challenge for simulations. At present, most simulations include non-LTE effects by invoking highly simplified inline models. These inline non-LTE models are both much slower than table look-up and significantly less accurate than the detailed models used to populate LTE tables and diagnose experimental data through post-processing or inversion. Because inline non-LTE models are slow, designers avoid them whenever possible, which leads to known inaccuracies from using tabular LTE. Because inline models are simple, they are inconsistent with tabular data from detailed models, leading to ill-known inaccuracies, and they cannot generate detailed synthetic diagnostics suitable for direct comparisons with experimental data. This project addresses the challenge of generating and utilizing efficient, accurate, and consistent non-equilibrium material data along three complementary but relatively independent research lines. First, we have developed a relatively fast and accurate non-LTE average-atom model based on density functional theory (DFT) that provides a complete set of EOS, transport, and radiative data, and have rigorously tested it against mo

Published

2022

17. Data publication: First-principles derivation and properties of density-functional average-atom models

Author

(0000-0002-4878-3521) Callow, T. J., Hansen, S. B., (0000-0003-0139-258X) Kraisler, E., (0000-0001-9162-262X) Cangi, A., (0000-0002-4878-3521) Callow, T. J., Hansen, S. B., (0000-0003-0139-258X) Kraisler, E., and (0000-0001-9162-262X) Cangi, A.

Abstract

Data for the pre-print "First-principles derivation and properties of density-functional average-atom models", https://arxiv.org/abs/2103.09928. Each data folder is named according to the corresponding figure in the paper. For any questions, please contact the authors.

Published

2022

18. Estimation of stagnation performance metrics in magnetized liner inertial fusion experiments using Bayesian data assimilation

Author

Knapp, P. F., primary, Glinsky, M. E., additional, Schaeuble, M. A., additional, Jennings, C. A., additional, Evans, M., additional, Gunning, J., additional, Awe, T. J., additional, Chandler, G. A., additional, Geissel, M., additional, Gomez, M. R., additional, Hahn, K. D., additional, Hansen, S. B., additional, Harding, E. C., additional, Harvey-Thompson, A. J., additional, Humane, S., additional, Klein, B. T., additional, Mangan, M., additional, Nagayama, T., additional, Porwitzky, A. J., additional, Ruiz, D. E., additional, Schmit, P. F., additional, Slutz, S. A., additional, Smith, I. C., additional, Weis, M. R., additional, Yager-Elorriaga, D. A., additional, Ampleford, D. J., additional, Beckwith, K., additional, Mattsson, T. R., additional, Peterson, K. J., additional, and Sinars, D. B., additional

Published

2022

19. First-principles derivation and properties of density-functional average-atom models

Author

Callow, T. J., primary, Hansen, S. B., additional, Kraisler, E., additional, and Cangi, A., additional

Published

2022

20. Data publication: First-principles derivation and properties of density-functional average-atom models

Author

Callow, T. J., Hansen, S. B., Kraisler, E., and Cangi, A.

Abstract

Data for the pre-print "First-principles derivation and properties of density-functional average-atom models", https://arxiv.org/abs/2103.09928. Each data folder is named according to the corresponding figure in the paper. For any questions, please contact the authors.

Published

2022