Improved long-term electrical stability of pulsed high-power diodes using dense carbon fiber velvet cathodes

Abstract

The influence of fibrous velvet cathodes on the electrical stability of a planar high-power diode powered by a ∼230 kV, ∼110 ns pulse has been investigated. The current density was on the order of ∼123 A/cm2. A combination of time-resolved electrical and optical diagnostics has been employed to study the basic phenomenology of the temporal and spatial evolution of the diode plasmas. Additionally, an impedance model was used to extract information about this plasma from voltage and current profiles. The results from the two diagnostics were compared. By comparison with commercial polymer velvet cathode, the dense carbon fiber velvet cathode showed superior long-term electrical stability as judged by the change in cathode turn-on field, ignition delays, diode impedance, and surface plasma characteristics during the voltage flattop, a promising result for applications where reliable operation at high power is required. Finally, it was shown that the interaction of the electron beam with the stainless steel anode did not lead to the formation of anode plasma. These results may be of interest to the high power microwave systems with cold cathodes.