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Mass motion and heating in a magnetic neutral point system

Published online by Cambridge University Press:  13 March 2009

P. J. Baum
Affiliation:
Physics Department, University of California, Riverside
A. Bratenahl
Affiliation:
Institute of planetary Physics, University of California, Riverside

Abstract

We present optical spectroscopic and magnetic probe observations of a laboratory discharge device, in which magnetic field line reconnexion occurs at an x−type neutral point. Time-resolved spectral-line profiles of the ionized argon line A II λ4348 are presented. These allow the determination of Doppler shifts and broadenings near the neutral point. Plasma heating occurs at the neutral point and downstream from it. Plasma is ejected from the downstream sides of the neutral point region at the local Alfvén speed at all times. This is equal to about one-tenth the upstream Alfvén speed at the one time it is known. The downstream magnetic Mach number or ‘local reconnexion rate’ is found to be nearly independent of the plasma conductivity and time. The rate of transfer of magnetic flux from the upstream to downstream regions is strongly dependent on conductivity and time.

Type
Research Article
Copyright
Copyright © Cambridge University Press 1974

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References

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