Modeling of impedance collapse in high-voltage diodes

Author

Turchi, Peter J. ; Peterkin, Robert E., Jr.

Author_Institution

Air Force Res. Lab., Kirtland AFB, NM, USA

Volume

26

Issue

5

fYear

1998

fDate

10/1/1998 12:00:00 AM

Firstpage

1485

Lastpage

1491

Abstract

Electron-beam diodes driven by fast-rising, high-voltage pulses often operate with cold cathodes for which the presence of a plasma adjacent to the cathode surface is essential to obtain adequate electron emission. A consequence of such surface plasma, however, is closure of the interelectrode gap by plasma motion. Resistive heating of the plasma competes with work performed in expanding the plasma and heat transfer to the cold-cathode boundary. The resulting closure speed is calculated, using an MHD code, and found to agree well with results of experiments using organic-cloth cathodes at 35 kV. Computed plasma speeds are typically 8-12 km/s, and are relatively insensitive to the applied voltage. Gap closure due to the plasma motion calculated numerically corresponds to estimates based on impedance collapse in the experiments

Keywords

cathodes; diodes; electron emission; heat transfer; high-voltage techniques; plasma diodes; 35 kV; MHD code; applied voltage; cathode surface; cold cathodes; cold-cathode boundary; electron emission; electron-beam diodes; fast-rising high-voltage pulses; gap closure; high-voltage diodes; impedance collapse; modeling; numerical calculation; organic-cloth cathodes; plasma; plasma motion; plasma resistive heating; Cathodes; Diodes; Heat transfer; Magnetohydrodynamics; Plasma density; Plasma properties; Plasma simulation; Plasma temperature; Surface impedance; Voltage;

fLanguage

English

Journal_Title

Plasma Science, IEEE Transactions on

Publisher

ieee

ISSN

0093-3813

Type

jour

DOI

10.1109/27.736043

Filename

736043