Modeling the effects of an axial magnetic field on the vacuum arc

A quantitative two-dimensional model of a vacuum arc in an applied magnetic field is presented. For the particular case, a uniform axial magnetic field B/sub Z/, it provides a unified condition for the two regimes of arc voltage versus B/sub Z/, i.e. ? the steeply falling voltage branch (low B/sub Z...

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Bibliographic Details
Published in:IEEE transactions on plasma science 2001-10, Vol.29 (5), p.684-689
Main Authors: Keidar, M., Schulman, M.B.
Format: Article
Language:English
Subjects:
Anodes
Cathodes
Contact
Diffusion
Electric potential
Electricity
Experiments
Falling
Interrupters
Magnetic fields
Magnetism
Mathematical models
Plasma applications
Plasma density
Plasma measurements
Plasma properties
Vacuum arcs
Voltage
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Summary:A quantitative two-dimensional model of a vacuum arc in an applied magnetic field is presented. For the particular case, a uniform axial magnetic field B/sub Z/, it provides a unified condition for the two regimes of arc voltage versus B/sub Z/, i.e. ? the steeply falling voltage branch (low B/sub Z/), and the slowly rising voltage branch (high B/sub Z/, which characterizes the diffuse arc mode). The transition to the high-B/sub Z/ regime is complete when the average mixing distance of the individual expanding cathode-spot plasma jets, measured from the cathode plane, is equal to the contact gap length. The model also predicts the observed smooth transition and minimum arc voltage between the two branches, and the independence of the are voltage on the arc current in the high-B/sub Z/ regime. Calculated results are found to be in good agreement with reported experimental data from several independent investigations over a wide range of gap, B/sub Z/ and arc current I/sub ARC/.
ISSN:0093-3813
1939-9375
DOI:10.1109/27.964454