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Title
Japanese: 
English:ExB Drift of Electrons in a Radial Electric Field and Longitudinal Magnetic Field 
Author
Japanese: 武田遵, 根津篤, 赤塚洋.  
English: Jun Takeda, Atsushi Nezu, Hiroshi Akatsuka.  
Language English 
Journal/Book name
Japanese: 
English:IEEE Transactions on Plasma Science 
Volume, Number, Page Vol. 47    No. 9    pp. 4250-4259
Published date Aug. 2, 2019 
Publisher
Japanese: 
English:IEEE 
Conference name
Japanese: 
English: 
Conference site
Japanese: 
English: 
Official URL https://ieeexplore.ieee.org/document/8786916
 
DOI https://doi.org/10.1109/TPS.2019.2928845
Abstract To examine the effect of the radial electric field on the electron rotational motion under ExB field, particularly Er x Bz geometry, for a plasma with magnetized electrons and nonmagnetized ions flowing through a uniform magnetic channel, an experimental study is conducted by applying a steady-state plasma flow along the uniform longitudinal magnetic field Bz. The argon plasma flow is generated by atmospheric-pressure dc arc discharge, followed by a continuous expansion into a rarefied gas-wind tunnel with a uniform magnetic field 0.15 T. Inside one of the magnets which is situated at rather a downstream position, a ring electrode is set to apply the radial electric field Er. An up-down probe is employed for the analysis of the electron azimuthal rotational motion. The value of the radial electric field applied in the plasma is about ~150 V/m. The probe measurement indicates the ExB rotation of electrons, particularly when the radially inward electric field is externally applied, whose order is about ~1000 m/s. The inward electric field results in the electron rotational motion in the same direction as the diamagnetic current. On the other hand, when the outward electric field is applied, the electron rotational motion is not observed. The order of the observed electron drift velocity is consistent with the theoretical value. ExB rotation velocity is found to be almost equal to that by the electron diamagnetic current. Even without the external electric field, the observed electron saturation current indicates that there is a rotational motion of electrons, which is considered to be due to the electron diamagnetic current.

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