Your search keyword '"Peterson, K. J."' showing total 5 results

1. Origins and effects of mix on magnetized liner inertial fusion target performance.

Author

Knapp, P. F., Gomez, M. R., Hansen, S. B., Glinsky, M. E., Jennings, C. A., Slutz, S. A., Harding, E. C., Hahn, K. D., Weis, M. R., Evans, M., Martin, M. R., Harvey-Thompson, A. J., Geissel, M., Smith, I. C., Ruiz, D. E., Peterson, K. J., Jones, B. M., Schwarz, J., Rochau, G. A., and Sinars, D. B.

Subjects

MAGNETIZATION, INERTIAL confinement fusion, ACCELERATION (Mechanics), NUCLEAR engineering

Abstract

In magneto-inertial-fusion experiments, energy losses such as a radiation need to be well controlled in order to maximize the compressional work done on the fuel and achieve thermonuclear conditions. One possible cause for high radiation losses is high-Z material mixing from the target components into the fuel. In this work, we analyze the effects of mix on target performance in Magnetized Liner Inertial Fusion (MagLIF) experiments at Sandia National Laboratories. Our results show that mix is likely produced from a variety of sources, approximately half of which originates during the laser heating phase and the remainder near stagnation, likely from the liner deceleration. By changing the "cushion" component of MagLIF targets from Al to Be, we achieved a 10× increase in neutron yield, a 60% increase in ion temperature, and an ∼50% increase in fuel energy at stagnation. [ABSTRACT FROM AUTHOR]

Published

2019

2. Design and testing of a magnetically driven implosion peak current diagnostic.

Author

Hess, M. H., Peterson, K. J., Ampleford, D. J., Hutsel, B. T., Jennings, C. A., Gomez, M. R., Dolan, D. H., Robertson, G. K., Payne, S. L., Stygar, W. A., Martin, M. R., and Sinars, D. B.

Subjects

*PULSED power systems, *INTERFEROMETERS, *MAGNETISM, *DOPPLER velocimetry

Abstract

A critical component of the magnetically driven implosion experiments at Sandia National Laboratories is the delivery of high-current, 10s of MA, from the Z pulsed power facility to a target. In order to assess the performance of the experiment, it is necessary to measure the current delivered to the target. Recent Magnetized Liner Inertial Fusion (MagLIF) experiments have included velocimetry diagnostics, such as PDV (Photonic Doppler Velocimetry) or Velocity Interferometer System for Any Reflector, in the final power feed section in order to infer the load current as a function of time. However, due to the nonlinear volumetrically distributed magnetic force within a velocimetry flyer, a complete time-dependent load current unfold is typically a time-intensive process and the uncertainties in the unfold can be difficult to assess. In this paper, we discuss how a PDV diagnostic can be simplified to obtain a peak current by sufficiently increasing the thickness of the flyer. This effectively keeps the magnetic force localized to the flyer surface, resulting in fast and highly accurate measurements of the peak load current. In addition, we show the results of experimental peak load current measurements from the PDV diagnostic in recent MagLIF experiments. [ABSTRACT FROM AUTHOR]

Published

2018

3. Detection of an anomalous pressure on a magneto-inertial-fusion load current diagnostic.

Author

Hess, M. H., Hutsel, B. T., Jennings, C. A., VanDevender, J. P., Sefkow, A. B., Gomez, M. R., Knapp, P. F., Laity, G. R., Dolan, D. H., Lamppa, D. C., Peterson, K. J., Stygar, W. A., and Sinars, D. B.

Subjects

INERTIAL confinement fusion, PLASMA diagnostics, PLASMA currents, PHYSICS experiments, DOPPLER velocimetry

Abstract

Recent Magnetized Liner Inertial Fusion experiments at the Sandia National Laboratories Z pulsed power facility have featured a PDV (Photonic Doppler Velocimetry) diagnostic in the final power feed section for measuring load current. In this paper, we report on an anomalous pressure that is detected on this PDV diagnostic very early in time during the current ramp. Early time load currents that are greater than both B-dot upstream current measurements and existing Z machine circuit models by at least 1 MA would be necessary to describe the measured early time velocity of the PDV flyer. This leads us to infer that the pressure producing the early time PDV flyer motion cannot be attributed to the magnetic pressure of the load current but rather to an anomalous pressure. Using the MHD code ALEGRA, we are able to compute a time-dependent anomalous pressure function, which when added to the magnetic pressure of the load current, yields simulated flyer velocities that are in excellent agreement with the PDV measurement. We also provide plausible explanations for what could be the origin of the anomalous pressure. [ABSTRACT FROM AUTHOR]

Published

2017

4. Monochromatic Soft X-Ray Self-Emission Imaging in Dense Z Pinches.

Author

Jones, B., Deeney, C., Meyer, C. J., Coverdale, C. A., LePell, P. D., Apruzese, J. P., Clark, R. W., Davis, J., and Peterson, K. J.

Subjects

GRENZ rays, X-rays, SPECTRUM analysis, SPECTRAL energy distribution

Abstract

The Z machine at Sandia National Laboratories drives 20 MA in 100 ns through a cylindrical array of fine wires which implodes due to the strong j × B force, generating up to 250 TW of soft x-ray radiation when the z-pinch plasma stagnates on axis. The copious broadband self-emission makes the dynamics of the implosion well suited to diagnosis with soft x-ray imaging and spectroscopy. A monochromatic self-emission imaging instrument has recently been developed on Z which reflects pinhole images from a multilayer mirror onto a 1 ns gated microchannel plate detector. The multilayer can be designed to provide narrowband (∼10 eV) reflection in the 100–700 eV photon energy range, allowing observation of the soft emission from accreting mass as it assembles into a hot, dense plasma column on the array axis. In the present instrument configuration, data at 277 eV photon energy have been obtained for plasmas ranging from Al to W, and the z-pinch implosion and stagnation will be discussed along with > 1 keV self-emission imaging and spectroscopy. Collisional-radiative simulations are currently being pursued in order to link the imaged emissivity to plasma temperature and density profiles and address the role of opacity in interpreting the data. © 2007 American Institute of Physics [ABSTRACT FROM AUTHOR]

Published

2007

5. 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