Time-Dependent Description of Cathode Crater Formation in Vacuum Arcs

Abstract

A dynamic model describing crater formation on the cathode of a metal vapor arc is solved numerically. The model takes into account phase changes, Joule and ionic heating, electron emission, and mass loss due to evaporation and ejection of molten metal. The calculation yields crater radius, crater formation time, erosion rate, and mean spot velocity; the values agree well with available experimental data. The vacuum arc phenomena "minimal arc current" and "spot-splitting current" are explained theoretically. The mean current density in the spot is about 1012 A/m2. The relative importance of ionic heating with regard to Joule heating depends on the cathode material and current density. The increase of crater radius with temperature is not because of reduced heat conduction into the solid.

Keywords

This publication has 29 references indexed in Scilit:

Numerical Simulation of High-Current Vacuum Arcs Under Axial Magnetic Fields With Consideration of Current Density Distribution at Cathode
IEEE Transactions on Plasma Science, 2011
On the variety of cathode craters of vacuum arcs, and the influence of the cathode temperature
Physica B+C, 1982
Formation time and heating mechanism of arc cathode craters in vacuum
Journal of Physics D: Applied Physics, 1981
Erosion Craters and Arc Cathode Spots in Vacuum
Contributions to Plasma Physics, 1979
Experimental Study of the Dynamics of Cathode Spots Development
IEEE Transactions on Plasma Science, 1976
On the inevitability of non-stationary vacuum arc spot models
Physics Letters A, 1974
Diameter and Current Density of Single and Multiple Cathode Discharges in Vacuum
IEEE Transactions on Power Apparatus and Systems, 1974
The vacuum switch. Part 1: Properties of the vacuum arc
Proceedings of the Institution of Electrical Engineers, 1963
Experimental Study of Arc Stability. I
Journal of Applied Physics, 1960
The Cathode Drop in an Electric Arc
Physical Review B, 1929

Cited by 38 articles