Publications

A Marx generator module from the decommissioned RITS pulsed power machine from Sandia National Labs was modified to operate in an existing setup at Texas Tech University. This will ultimately be used as a testbed for laser triggered gas switching. The existing experimental setup at Texas Tech University consists of a large Marx tank, an oil-filled coaxial pulse forming line, an adjustable peaking gap, and load section along with various diagnostics. The setup was previously operated at a lower voltage than the new experiment, so electrostatic modeling was done to ensure viability and drive needed modifications. The oil tank will house the modified RITS Marx. This Marx contains half as many stages as the original RITS module and has an expected output of 1 MV. A trigger Marx generator consisting of 8 stages has been fabricated to trigger the RITS Marx. Charging and triggering of both Marx generators will be controlled through a fiber optic network. The output from the modified RITS Marx will be used to charge the oil-filled coaxial line acting as a low impedance pulse forming line (PFL). Once charged, the self-breaking peaking gap will close, allowing the compressed pulse to be released into the load section. For testing of the Marx module and PFL, a match 10 Ω water load was fabricated. The output pulsewidth is 55 nsec. Diagnostics include two capacitive voltage probes on either side of the peaking gap, a quarter-turn Rogowski coil for load current measurement, and a Pearson coil for calibrations purposes.

This primary purpose of this project was to evaluate alternative gas mixtures to sulfur hexafluoride (SF6) developed for high voltage power delivery applications for use in high voltage spark gap switches. These SF6 alternatives lower global warming potential emissions and enable improvements to the pressure-voltage design space. A combined experimental, computational, and theoretical study was used to quantify the impact of persistent breakdown products on the breakdown distribution of SF6-replacement gas mixtures. Viable SF6 replacements suitable for use in spark gap switches were studied to enable performance and agility improvements for next-generation pulsed power research relevant to national security missions. Experimental campaign included establishing parameters of switch gases as function of concentration. Various concentrations and pressures were tested for trends in breakdown voltage, repeatability, and durability, and breakdown constituents. A zero-dimensional plasma global model was used to simulate the plasma arc decay and recombination process in spark-gap switches relevant to the Z machine. Finally, a complete and consistent set of electron-neutral collision cross-sections for the novel insulating gas C4F7N is reported.