Publications

Cuneo, M.E.; Stoltzfus, Brian S.; Stygar, William A.; Woodworth, Joseph R.; Davis, Jean-Paul D.; Glover, Steven F.; LeChien, Keith R.; Leckbee, Joshua L.; Mazarakis, Michael G.; McKee, George R.; Savage, Mark E.

Abstract not provided.

LeChien, Keith R.; Fowler, William E.; Mazarakis, Michael G.; Stygar, William A.; Long, Finis W.; McKee, George R.; Natoni, Gregory N.

Abstract not provided.

LeChien, Keith R.; Fowler, William E.; Mazarakis, Michael G.; Stygar, William A.; Long, Finis W.; McKee, George R.; Natoni, Gregory N.

Abstract not provided.

LeChien, Keith R.; Stygar, William A.; Savage, Mark E.; McKee, George R.; Bliss, David E.

Abstract not provided.

Owen, Albert C.; Garde, J.; Stygar, William A.; McKee, George R.

Abstract not provided.

Proposed for publication in Physical Review Special Topics: Accelerators and Beams.

Stygar, William A.; Stoltzfus, Brian S.; Woodworth, Joseph R.; Fowler, William E.; LeChien, Keith R.; Long, Finis W.; Mazarakis, Michael G.; McKee, George R.; Mckenney, John M.; Savage, Mark E.

We demonstrate that a wide variety of current-pulse shapes can be generated using a linear-transformer-driver (LTD) module that drives an internal water-insulated transmission line. The shapes are produced by varying the timing and initial charge voltage of each of the module's cavities. The LTD-driven accelerator architecture outlined in [Phys. Rev. ST Accel. Beams 10, 030401 (2007)] provides additional pulse-shaping flexibility by allowing the modules that drive the accelerator to be triggered at different times. The module output pulses would be combined and symmetrized by water-insulated radial-transmission-line impedance transformers [Phys. Rev. ST Accel. Beams 11, 030401 (2008)].

Struve, Kenneth W.; Savage, Mark E.; Stygar, William A.; Weed, John W.; Weinbrecht, Edward A.; Cuneo, M.E.; Bloomquist, Douglas D.; Davis, Jean-Paul D.; LeChien, Keith R.; Matzen, M.K.; McKee, George R.; McDaniel, Dillon H.

Abstract not provided.

Matzen, M.K.; Long, Finis W.; McKee, George R.; Mehlhorn, Thomas A.; Schneider, Larry X.; Struve, Kenneth W.; Stygar, William A.; Weinbrecht, Edward A.; Atherton, B.W.; Cuneo, M.E.; Donovan, Guy L.; Hall, Clint A.; Herrmann, Mark H.; Kiefer, Mark L.; Leeper, Ramon J.; Leifeste, Gordon T.

The Z Refurbishment Project was completed in September 2007. Prior to the shutdown of the Z facility in July 2006 to install the new hardware, it provided currents of {le} 20 MA to produce energetic, intense X-ray sources ({approx} 1.6 MJ, > 200 TW) for performing high energy density science experiments and to produce high magnetic fields and pressures for performing dynamic material property experiments. The refurbishment project doubled the stored energy within the existing tank structure and replaced older components with modern, conventional technology and systems that were designed to drive both short-pulse Z-pinch implosions and long-pulse dynamic material property experiments. The project goals were to increase the delivered current for additional performance capability, improve overall precision and pulse shape flexibility for better reproducibility and data quality, and provide the capacity to perform more shots. Experiments over the past year have been devoted to bringing the facility up to full operating capabilities and implementing a refurbished suite of diagnostics. In addition, we have enhanced our X-ray backlighting diagnostics through the addition of a two-frame capability to the Z-Beamlet system and the addition of a high power laser (Z-Petawatt). In this paper, we will summarize the changes made to the Z facility, highlight the new capabilities, and discuss the results of some of the early experiments.

Bloomquist, Douglas D.; McDaniel, Dillon H.; McKee, George R.; Donovan, Guy L.; Weed, John W.; Faturos, Thomas V.; Tabor, Debra A.; Jordan, Carla M.

Sandia's Z Refurbishment (ZR) Project formally began in February 2002 to increase the Z Accelerator's utilization by providing the capability to perform more shots, improve precision and pulse shape variability, and increase delivered current. A project update was provided at the 15th International Pulsed Power Conference in 2005. The Z facility was shut down in July 2006 for structural/infrastructure modifications and installation of new pulsed power systems. The refurbishment will conclude in 2007. This paper provides a status update of the project covering the past 2 years of activities.

Bloomquist, Douglas D.; McDaniel, Dillon H.; McKee, George R.; Donovan, Guy L.; Weed, John W.; Faturos, Thomas V.; Jordan, Carla M.; Weinbrecht, Edward A.

Abstract not provided.

Maenchen, John E.; Savage, Mark E.; Struve, Kenneth W.; Woodworth, Joseph R.; Lehr, J.M.; Warne, Larry K.; Bliss, David E.; Jorgenson, Roy E.; LeChien, Keith R.; McKee, George R.; Pasik, Michael F.; Rosenthal, Stephen E.

In October 2005, an intensive three-year Laser Triggered Gas Switch (LTGS) development program was initiated to investigate and solve observed performance and reliability issues with the LTGS for ZR. The approach taken has been one of mission-focused research: to revisit and reassess the design, to establish a fundamental understanding of LTGS operation and failure modes, and to test evolving operational hypotheses. This effort is aimed toward deploying an initial switch for ZR in 2007, on supporting rolling upgrades to ZR as the technology can be developed, and to prepare with scientific understanding for the even higher voltage switches anticipated needed for future high-yield accelerators. The ZR LTGS was identified as a potential area of concern quite early, but since initial assessments performed on a simplified Switch Test Bed (STB) at 5 MV showed 300-shot lifetimes on multiple switch builds, this component was judged acceptable. When the Z{sub 20} engineering module was brought online in October 2003 frequent flashovers of the plastic switch envelope were observed at the increased stresses required to compensate for the programmatically increased ZR load inductance. As of October 2006, there have been 1423 Z{sub 20} shots assessing a variety of LTGS designs. Numerous incremental and fundamental switch design modifications have been investigated. As we continue to investigate the LTGS, the basic science of plastic surface tracking, laser triggering, cascade breakdown, and optics degradation remain high-priority mission-focused research topics. Significant progress has been made and, while the switch does not yet achieve design requirements, we are on the path to develop successively better switches for rolling upgrade improvements to ZR. This report summarizes the work performed in FY 2006 by the large team. A high-level summary is followed by detailed individual topical reports.

McDaniel, Dillon H.; Struve, Kenneth W.; Weed, John W.; Weinbrecht, Edward A.; Woodworth, Joseph R.; Bliss, David E.; Bloomquist, Douglas D.; Harjes, Henry C.; Lehr, J.M.; Long, Finis W.; Maenchen, John E.; McKee, George R.; Savage, Mark E.

Abstract not provided.

Maenchen, John E.; Van Den Avyle, James A.; Warne, Larry K.; Woodworth, Joseph R.; Bliss, David E.; LeChien, Keith R.; Lehr, J.M.; McDaniel, Dillon H.; McKee, George R.; Savage, Mark E.; Struve, Kenneth W.

Abstract not provided.

Elizondo-Decanini, Juan M.; Bennett, Lawrence F.; Stoltzfus, Brian S.; Stygar, William A.; McKee, George R.

Abstract not provided.

Bloomquist, Douglas D.; McDaniel, Dillon H.; Weed, John W.; Faturos, Thomas V.; McKee, George R.; Tabor, Debra A.; Warner, Peggy J.

Sandia National Laboratories Z Refurbishment (ZR) Project formally began in August 2002 to increase the Z Accelerator's utilization by providing the capability to perform more shots, improve precision and pulse shape variability, increase delivered current, and accomplish the improvements with minimal disruption to Z's ongoing programs. A project overview was provided at the 14th International Pulsed Power Conference in 2003. This paper provides an update of the project including architectural changes over the past two years, timeframe for completion, and overall design and fabrication status.