The \(\alpha\) Dynamo Effects in Laboratory Plasmas

A concise review of observations of the \(\alpha\) dynamo effect in laboratory plasmas is given. Unlike many astrophysical systems, the laboratory pinch plasmas are driven magnetically. When the system is overdriven, the resultant instabilities cause magnetic and flow fields to fluctuate, and their...

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Bibliographic Details
Published inarXiv.org
Main Authors Ji, Hantao, Prager, Stewart C
Format Paper
LanguageEnglish
Published Ithaca Cornell University Library, arXiv.org 15.10.2001
Subjects
Diffusion rate
Electric potential
Electromotive forces
Helicity
Laboratories
Magnetic fields
Magnetic structure
Magnetism
Plasmas
Rotating generators
Variation
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Summary:A concise review of observations of the \(\alpha\) dynamo effect in laboratory plasmas is given. Unlike many astrophysical systems, the laboratory pinch plasmas are driven magnetically. When the system is overdriven, the resultant instabilities cause magnetic and flow fields to fluctuate, and their correlation induces electromotive forces along the mean magnetic field. This \(\alpha\)-effect drives mean parallel electric current, which, in turn, modifies the initial background mean magnetic structure towards the stable regime. This drive-and-relax cycle, or the so-called self-organization process, happens in magnetized plasmas in a time scale much shorter than resistive diffusion time, thus it is a fast and unquenched dynamo process. The observed \(\alpha\)-effect redistributes magnetic helicity (a measure of twistedness and knottedness of magnetic field lines) but conserves its total value. It can be shown that fast and unquenched dynamos are natural consequences of a driven system where fluctuations are statistically either not stationary in time or not homogeneous in space, or both. Implications to astrophysical phenomena will be discussed.
ISSN:2331-8422
DOI:10.48550/arxiv.0110352