Electrostatic ion acceleration in an inductive radio-frequency plasma thruster

Spatially and temporally resolved ion flow measurements are performed inside the plasma source of an inductive radio frequency plasma thruster. Using the resulting data, the pure effects of the inductive current drive on the ion flow are identified. The cross field ion acceleration and the establish...

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Veröffentlicht in:	Physics of plasmas 2020-10, Vol.27 (10), Article 103513
Hauptverfasser:	Sekine, H., Koizumi, H., Komurasaki, K.
Format:	Artikel
Sprache:	eng
Schlagworte:	Acceleration Electric fields Flow velocity Ion dynamics Magnetic fields Physical Sciences Physics Physics, Fluids & Plasmas Plasma physics Radio frequency plasma Science & Technology Superposition (mathematics)
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container_title	Physics of plasmas
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creator	Sekine, H. Koizumi, H. Komurasaki, K.
description	Spatially and temporally resolved ion flow measurements are performed inside the plasma source of an inductive radio frequency plasma thruster. Using the resulting data, the pure effects of the inductive current drive on the ion flow are identified. The cross field ion acceleration and the establishment of the cross field electric field are found in the upstream region, where the azimuthal current is induced by the superimposition of a time-varying magnetic field. Analyzing the electron and ion dynamics with two-fluid equations, the magnetized electrons form the in-plane Hall electric field to satisfy the electron force balance, which results in the electrostatic acceleration of unmagnetized ions. The enhanced density gradient forms a stronger Boltzmann electric field along the magnetic field. It generates a supersonic ion group along the magnetic field line, which increases the field-aligned ion flow velocity and the momentum thrust.
doi_str_mv	10.1063/5.0020395
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subjects	Acceleration Electric fields Flow velocity Ion dynamics Magnetic fields Physical Sciences Physics Physics, Fluids & Plasmas Plasma physics Radio frequency plasma Science & Technology Superposition (mathematics)
title	Electrostatic ion acceleration in an inductive radio-frequency plasma thruster
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