A Renewed Capability for Gas Puff Science on Sandia's Z Machine

A comprehensive gas puff capability is being developed on the Z pulsed power generator. We describe the methodology employed for developing a gas puff load on Z, which combines characterization and modeling of the neutral gas mass flow from a supersonic nozzle, numerical modeling of the implosion of...

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Bibliographic Details
Published in:IEEE transactions on plasma science Vol. 42; no. 5; pp. 1145 - 1152
Main Authors: Jones, Brent, Jennings, Christopher A., Lamppa, Derek C., Hansen, Stephanie B., Harvey-Thompson, Adam J., Ampleford, David J., Cuneo, Michael E., Strizic, Thomas, Johnson, Drew, Jones, Michael C., Moore, Nathan W., Flanagan, Timothy M., McKenney, John L., Waisman, Eduardo M., Coverdale, Christine A., Krishnan, Mahadevan, Coleman, Philip L., Elliott, Kristi Wilson, Madden, Robert E., Thompson, John, Bixler, Alex, Thornhill, J. Ward, Giuliani, John L., Chong, Young K., Velikovich, Alexander L., Dasgupta, Arati, Apruzese, John P.
Format: Journal Article
Language:English
Published: New York IEEE 01-05-2014
The Institute of Electrical and Electronics Engineers, Inc. (IEEE)
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Summary:A comprehensive gas puff capability is being developed on the Z pulsed power generator. We describe the methodology employed for developing a gas puff load on Z, which combines characterization and modeling of the neutral gas mass flow from a supersonic nozzle, numerical modeling of the implosion of this mass profile, and experimental evaluation of these magnetic implosions on Z. We are beginning a multiyear science program to study gas puff z-pinch physics at high current, starting with an 8-cm diameter double-shell nozzle, which delivers a column of Ar gas that is imploded by the machine's fast current pulse. The initial shots have been designed using numerical simulation with two radiation-magnetohydrodynamic codes. These calculations indicate that 1 mg/cm should provide optimal coupling to the driver and 1.6:1 middle:outer shell mass ratio will best balance the need for high implosion velocity against the need to mitigate the magnetic Rayleigh-Taylor instability. The models suggest 300-500-kJ Ar K-shell yield should be achievable on Z, and we report an initial commissioning shot at lower voltage in which 250 kJ was measured. Future experiments will pursue optimization of Ar and Kr K-shell X-ray sources, study fusion in deuterium gas puffs, and investigate the physics of gas puff implosions including energy coupling, instability growth, and radiation generation.
ISSN:0093-3813
1939-9375
DOI:10.1109/TPS.2013.2287180