Your search keyword '"W. D. Tatum"' showing total 3 results

1. Evolution of Gas Cell Targets for Magnetized Liner Inertial Fusion Experiments at the Sandia National Laboratories PECOS Test Facility

Author

K. Tomlinson, R. R. Holt, A. J. Harvey-Thompson, G. E. Smith, R. R. Paguio, J. Kellogg, Michael Farrell, Kyle Peterson, J. Betcher, W. D. Tatum, J. L. Taylor, and Matthias Geissel

Subjects

Nuclear and High Energy Physics, Fabrication, Materials science, Backscatter, Mechanical Engineering, Nuclear engineering, Physics::Optics, Magnetized Liner Inertial Fusion, Plasma, Laser, 01 natural sciences, 010305 fluids & plasmas, law.invention, Pulse (physics), Nuclear Energy and Engineering, Filamentation, law, 0103 physical sciences, Deposition (phase transition), General Materials Science, Physics::Atomic Physics, 010306 general physics, Civil and Structural Engineering

Abstract

Z-beamlet experiments conducted at the PECOS test facility at Sandia National Laboratories (SNL) investigated the nonlinear processes in laser plasma interaction (or laser-plasma instabilities) that complicate the deposition of laser energy by enhanced absorption, backscatter, filamentation, and beam-spray that can occur in large-scale laser-heated gas cell targets. These targets and experiments were designed to provide better insight into the physics of the laser preheat stage of the Magnetized Liner Inertial Fusion scheme being tested on the SNL Z-machine. The experiments aim to understand the trade-offs between laser spot size, laser pulse shape, laser entrance hole window thickness, and fuel density for laser preheat. Gas cell target design evolution and fabrication adaptations to accommodate the evolving experiment and scientific requirements are described in this paper.

Published

2017

2. Development of a Multi-Press Assembly Device for Planar Dynamic Material Property Targets

Author

G. E. Smith, J. L. Taylor, R. R. Holt, K. Tomlinson, Michael Farrell, R. R. Paguio, and W. D. Tatum

Subjects

Nuclear and High Energy Physics, Fabrication, Property (programming), Computer science, Mechanical Engineering, Window (computing), Mechanical engineering, 02 engineering and technology, Pulsed power, 021001 nanoscience & nanotechnology, 01 natural sciences, Planar, Nuclear Energy and Engineering, Stack (abstract data type), 0103 physical sciences, General Materials Science, New device, Development (differential geometry), 010306 general physics, 0210 nano-technology, Civil and Structural Engineering

Abstract

A class of dynamic material property (DMP) experiments on the Sandia National Laboratories pulse power Z-Machine requires planar samples to be held in a panel assembly. A custom press device to fabricate the assemblies has the ability to assemble one sample, window, or stack at a time, resulting in a 1-week lead time for a typical three-pocket panel assembly. Fabrication of targets with more than three pockets can take longer. In late 2015, General Atomics conceptualized a new multi-press device to enable several samples, windows, or stacks to be assembled simultaneously, and a prototype was designed, procured, and outfitted in 6 months. Since June 2016, this multi-press design has successfully assembled 60 planar DMP targets. The development considerations for this new device and the resulting benefits for the fabrication of targets are discussed.

Published

2017

3. Seeding the explosion of a high-current-density conductor in a controlled manner through the addition of micron-scale surface defects

Author

Thomas James Awe, Brian Hutsel, M. W. Hatch, K. Tomlinson, T. M. Hutchinson, K. C. Yates, W. D. Tatum, Bruno S. Bauer, and Edmund Yu

Subjects

Physics, Protein filament, Resistive touchscreen, Electrical resistivity and conductivity, Plasma, Mechanics, Condensed Matter Physics, Joule heating, Current density, Overheating (electricity), Conductor

Abstract

Inhomogeneities in a current-carrying conductor promote non-uniform heating and expansion through the complex feedback between current density, electrical resistivity, Ohmic heating, temperature, and hydrodynamics. Three-dimensional-magnetohydrodynamic (3D-MHD) simulations suggest that μm-scale resistive inclusions or voids seed local overheating and through hydrodynamic explosion generate continuously growing craters which become several times larger than the initial perturbation. The ejected mass is the genesis of an electrothermally driven plasma filament which develops at lower current than plasmas on uniform surfaces adjacent to the defect. This result suggests that 1D or even 2D treatments are largely inadequate for detailed prediction of plasma formation. To test computational predictions, z-pinch experiments driven to 1 MA studied ultra-high-purity aluminum rods which were then machined to include pairs of quasi-hemispherical voids or “engineered defects (ED)” on the current-carrying surface. ED are the dominant current-density perturbation and reproducibly drive local overheating which can be compared with 3D-MHD simulation. Data from high-resolution-gated imagers of visible surface emissions confirm many simulation predictions, including the surface topography of local overheating, and the propensity for neighboring ED to prematurely source plasmas which then connect to form a plasma filament. Results also provide conditional support of theory which suggests heating similarity; that is, heating is independent of ED size for geometrically scaled ED.

Published

2021