Title :
Plasma diagnostics for high power ignitron development
Author :
Loree, D.L. ; Giesselmann, M. ; Kristiansen, M. ; Shulski, A.
Author_Institution :
Texas Tech. Univ., Lubbock, TX, USA
fDate :
1/1/1991 12:00:00 AM
Abstract :
A description is given of plasma diagnostics performed on a demountable ignitron (DIG) which provides optical access to the discharge plasma through four viewports, two of which are on opposite sides on a common optical axis. The latter pair of viewports was used to perform plasma density studies using a Mach-Zehnder interferometer. Time-resolved recordings of the interference patterns, either visual or electronic, during changes in plasma behavior (such as current conduction or plasma heating) yield time-resolved information about the particle density. This technique was applied to the DIG during high-current discharges. The light source was a 2 W CW argon laser which was pulsed using a ferroelectric liquid crystal light valve. The resulting fringe patterns were recorded with a mechanical high-speed camera. All experimental details, results and a theoretical evaluation are given. In addition, high-speed framing photography was used to study the influence on electrode design and placement on the discharge plasma
Keywords :
light interferometry; mercury arc rectifiers; plasma density; plasma devices; plasma diagnostics; plasma diagnostics by laser beam; 1000 kA; Mach-Zehnder interferometer; NL-9000; continuous wave Ar laser; current conduction; demountable ignitron; discharge plasma; electrode design; ferroelectric liquid crystal light valve; fringe patterns; high power ignitron development; high-current discharges; high-speed framing photography; interference patterns; light source; mechanical high-speed camera; optical access; optical plasma studies; plasma density studies; plasma heating; time-resolved recordings; Fault location; Heating; High speed optical techniques; Interference; Light sources; Optical interferometry; Optical recording; Plasma density; Plasma diagnostics; Plasma sources;
Journal_Title :
Magnetics, IEEE Transactions on
