Your search keyword '"Hansen, S. B."' showing total 8 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., and Shipley, G. A.

Subjects

MAGNETIC reconnection, OPTICAL spectroscopy, MAGNETIC fields, X-ray imaging, EMISSION spectroscopy, SPHEROMAKS

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 ≈ 7) with anti-parallel magnetic fields, which form a reconnection layer ( S L ≈ 120) at the mid-plane. The net cooling rate far exceeds the Alfvénic transit rate ( τ cool − 1 / τ A − 1 ≫ 1), 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 (≤ 75 eV) and inflow temperatures (about 2 eV) and that these hotspots generate the majority of the high-energy (> 1 keV) emission. [ABSTRACT FROM AUTHOR]

Published

2024

2. Magnetic field impact on the laser heating in MagLIF.

Author

Carpenter, K. R., Mancini, R. C., Harding, E. C., Harvey-Thompson, A. J., Geissel, M., Weis, M. R., Hansen, S. B., Peterson, K. J., and Rochau, G. A.

Subjects

MAGNETIC fields, HIGH temperature plasmas, ELECTRON temperature, LASER plasmas, ELECTRON distribution, INERTIAL confinement fusion, MAGNETIC nanoparticle hyperthermia

Abstract

Prior to implosion in Magnetized Liner Inertial Fusion (MagLIF), the fuel is heated to temperatures on the order of several hundred eV with a multi-kJ, multi-ns laser pulse. We present two laser heated plasma experiments, relevant to the MagLIF preheat stage, performed at Z with beryllium liners filled with deuterium and a trace amount of argon. In one experiment, there is no magnetic field and, in the other, the liner and fuel are magnetized with an 8.5 T axial magnetic field. The recorded time integrated, spatially resolved spectra of the Ar K-shell emission are sensitive to electron temperature Te. Individual analysis of the spatially resolved spectra produces electron temperature distributions Te(z) that are resolved along the axis of laser propagation. In the experiment with magnetic field, the plasma reaches higher temperatures and the heated region extends deeper within the liner than in the unmagnetized case. Radiation magnetohydrodynamics simulations of the experiments are presented and post-processed. A comparison of the results from experimental and simulated data reveals that the simulations underpredict Te in both cases but the differences are larger in the case with magnetic field. [ABSTRACT FROM AUTHOR]

Published

2020

3. Effect of Axial Magnetic Flux Compression on the Magnetic Rayleigh-Taylor Instability (Theory).

Author

Ryutov, D. D., Awe, T. J., Hansen, S. B., McBride, R. D., Peterson, K. J., Sinars, D. B., and Slutz, S. A.

Subjects

MAGNETIC flux compression, RAYLEIGH-Taylor instability, PLASMA instabilities, MAGNETIC fields, QUANTUM perturbations

Abstract

Possible effects on the liner implosion of an early plasma formation outside the liner are discussed. At the modest density and temperature this plasma is a sufficiently good conductor to trap the pre-imposed axial magnetic field. The rising axial current compresses the plasma and axial field towards the liner surface and creates high-magnetic-field filamentary structures that seed the perturbations by the mechanism proposed in Ref. 1, but in a significantly higher field. Possible sources of this plasma are briefly discussed. [ABSTRACT FROM AUTHOR]

Published

2014

4. Exploring magnetized liner inertial fusion with a semi-analytic model.

Author

McBride, R. D., Slutz, S. A., Vesey, R. A., Gomez, M. R., Sefkow, A. B., Hansen, S. B., Knapp, P. F., Schmit, P. F., Geissel, M., Harvey-Thompson, A. J., Jennings, C. A., Harding, E. C., Awe, T. J., Rovang, D. C., Hahn, K. D., Martin, M. R., Cochrane, K. R., Peterson, K. J., Rochau, G. A., and Porter, J. L.

Subjects

INERTIAL confinement fusion, MAGNETIZATION, MAGNETIC fields, SIMULATION methods & models, ELECTRIC currents

Abstract

In this paper, we explore magnetized liner inertial fusion (MagLIF) [S. A. Slutz et al., Phys. Plasmas 17, 056303 (2010)] using a semi-analytic model [R. D. McBride and S. A. Slutz, Phys. Plasmas 22, 052708 (2015)]. Specifically, we present simulation results from this model that: (a) illustrate the parameter space, energetics, and overall system efficiencies of MagLIF; (b) demonstrate the dependence of radiative loss rates on the radial fraction of the fuel that is preheated; (c) explore some of the recent experimental results of the MagLIF program at Sandia National Laboratories [M. R. Gomez et al., Phys. Rev. Lett. 113, 155003 (2014)]; (d) highlight the experimental challenges presently facing the MagLIF program; and (e) demonstrate how increases to the preheat energy, fuel density, axial magnetic field, and drive current could affect future MagLIF performance. [ABSTRACT FROM AUTHOR]

Published

2016

5. Effects of magnetization on fusion product trapping and secondary neutron spectra.

Author

Knapp, P. F., Schmit, P. F., Hansen, S. B., Gomez, M. R., Hahn, K. D., Sinars, D. B., Peterson, K. J., Slutz, S. A., Sefkow, A. B., Awe, T. J., Harding, E., Jennings, C. A., Desjarlais, M. P., Chandler, G. A., Cooper, G. W., Cuneo, M. E., Geissel, M., Harvey-Thompson, A. J., Porter, J. L., and Rochau, G. A.

Subjects

MAGNETIZATION, NEUTRON spectroscopy, INERTIAL confinement fusion, STAGNATION pressure, MAGNETIC fields

Abstract

By magnetizing the fusion fuel in inertial confinement fusion (ICF) systems, the required stagnation pressure and density can be relaxed dramatically. This happens because the magnetic field insulates the hot fuel from the cold pusher and traps the charged fusion burn products. This trapping allows the burn products to deposit their energy in the fuel, facilitating plasma self-heating. Here, we report on a comprehensive theory of this trapping in a cylindrical DD plasma magnetized with a purely axial magnetic field. Using this theory, we are able to show that the secondary fusion reactions can be used to infer the magnetic field-radius product, BR, during fusion burn. This parameter, not ρR, is the primary confinement parameter in magnetized ICF. Using this method, we analyze data from recent Magnetized Liner Inertial Fusion experiments conducted on the Z machine at Sandia National Laboratories. We show that in these experiments BR ≈ 0.34(+0.14/−0.06) MG · cm, a ~ 14× increase in BR from the initial value, and confirming that the DD-fusion tritons are magnetized at stagnation. This is the first experimental verification of charged burn product magnetization facilitated by compression of an initial seed magnetic flux. [ABSTRACT FROM AUTHOR]

Published

2015

6. Modified helix-like instability structure on imploding z-pinch liners that are pre-imposed with a uniform axial magnetic field.

Author

Awe, T. J., Jennings, C. A., McBride, R. D., Cuneo, M. E., Lamppa, D. C., Martin, M. R., Rovang, D. C., Sinars, D. B., Slutz, S. A., Owen, A. C., Tomlinson, K., Gomez, M. R., Hansen, S. B., Herrmann, M. C., Jones, M. C., McKenney, J. L., Robertson, G. K., Rochau, G. A., Savage, M. E., and Schroen, D. G.

Subjects

MAGNETIC fields, INERTIAL confinement fusion, AZIMUTH, PLASMA instabilities, RAYLEIGH-Taylor instability

Abstract

Recent experiments at the Sandia National Laboratories Z Facility have, for the first time, studied the implosion dynamics of magnetized liner inertial fusion (MagLIF) style liners that were preimposed with a uniform axial magnetic field. As reported [T. J. Awe et al., Phys. Rev. Lett. 111, 235005 (2013)] when premagnetized with a 7 or 10 T axial field, these liners developed 3D-helixlike hydrodynamic instabilities; such instabilities starkly contrast with the azimuthally correlated magneto-Rayleigh-Taylor (MRT) instabilities that have been consistently observed in many earlier non-premagnetized experiments. The helical structure persisted throughout the implosion, even though the azimuthal drive field greatly exceeded the expected axial field at the liner's outer wall for all but the earliest stages of the experiment. Whether this modified instability structure has practical importance for magneto-inertial fusion concepts depends primarily on whether the modified instability structure is more stable than standard azimuthally correlated MRT instabilities. In this manuscript, we discuss the evolution of the helix-like instability observed on premagnetized liners. While a first principles explanation of this observation remains elusive, recent 3D simulations suggest that if a small amplitude helical perturbation can be seeded on the liner's outer surface, no further influence from the axial field is required for the instability to grow. [ABSTRACT FROM AUTHOR]

Published

2014

7. Magnetically Driven Implosions for Inertial Confinement Fusion at Sandia National Laboratories.

Author

Cuneo, M. E., Herrmann, M. C., Sinars, D. B., Slutz, S. A., Stygar, W. A., Vesey, R. A., Sefkow, A. B., Rochau, G. A., Chandler, G. A., Bailey, J. E., Porter, J. L., McBride, R. D., Rovang, D. C., Mazarakis, M. G., Yu, E. P., Lamppa, D. C., Peterson, K. J., Nakhleh, C., Hansen, S. B., and Lopez, A. J.

Subjects

MAGNETIC fields, PINCH analysis, DEUTERIUM, HEATING

Abstract

High current pulsed-power generators efficiently store and deliver magnetic energy to z-pinch targets. We review applications of magnetically driven implosions (MDIs) to inertial confinement fusion. Previous research on MDIs of wire-array z-pinches for radiation-driven indirect-drive target designs is summarized. Indirect-drive designs are compared with new targets that are imploded by direct application of magnetic pressure produced by the pulsed-power current pulse. We describe target design elements such as larger absorbed energy, magnetized and pre-heated fuel, and cryogenic fuel layers that may relax fusion requirements. These elements are embodied in the magnetized liner inertial fusion (MagLIF) concept [Slutz “Pulsed-power-driven cylindrical liner implosions of laser pre-heated fuel magnetized with an axial field,” Phys. Plasmas, 17, 056303 (2010), and Stephen A. Slutz and Roger A. Vesey, “High-Gain Magnetized Inertial Fusion,” Phys. Rev. Lett., 108, 025003 (2012)]. MagLIF is in the class of magneto-inertial fusion targets. In MagLIF, the large drive currents produce an azimuthal magnetic field that compresses cylindrical liners containing pre-heated and axially pre-magnetized fusion fuel. Scientific breakeven may be achievable on the Z facility with this concept. Simulations of MagLIF with deuterium-tritium fuel indicate that the fusion energy yield can exceed the energy invested in heating the fuel at a peak drive current of about 27 MA. Scientific breakeven does not require alpha particle self-heating and is therefore not equivalent to ignition. Capabilities to perform these experiments will be developed on Z starting in 2013. These simulations and predictions must be validated against a series of experiments over the next five years. Near-term experiments are planned at drive currents of 16 MA with D2 fuel. MagLIF increases the efficiency of coupling energy (=target absorbed energy/driver stored energy) to targets by 10–150X relative to indirect-drive targets. MagLIF also increases the absolute energy absorbed by the target by 10-50X relative to indirect-drive targets. These increases could lead to higher fusion gains and yields. Single-shot high yields are of great utility to national security missions. Higher efficiency and higher gains may also translate into more compelling (lower cost and complexity) fusion reactor designs. We will discuss the broad goals of the emerging research on the MagLIF concept and identify some of the challenges. We will also summarize advances in pulsed-power technology and pulsed-power driver architectures that double the efficiency of the driver. [ABSTRACT FROM PUBLISHER]

Published

2012

8. Magnetic field measurements via visible spectroscopy on the Z machine.

Author

Gomez, M. R., Hansen, S. B., Peterson, K. J., Bliss, D. E., Carlson, A. L., Lamppa, D. C., Schroen, D. G., and Rochau, G. A.

Subjects

*MAGNETIC fields, *OPTICAL spectroscopy, *COMPUTER simulation, *SPECTRAL lines, *SCIENTIFIC apparatus & instruments

Abstract

Sandia's Z Machine uses its high current to magnetically implode targets relevant to inertial confinement fusion. Since target performance is highly dependent on the applied drive field, measuring magnetic field at the target is essential for accurate simulations. Recently, the magnetic field at the target was measured through splitting of the sodium 3s-3p doublet at 5890 and 5896 Å. Spectroscopic dopants were applied to the exterior of the target, and spectral lines were observed in absorption. Magnetic fields in excess of 200 T were measured, corresponding to drive currents of approximately 5 MA early in the pulse. [ABSTRACT FROM AUTHOR]

Published

2014