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Prof. Mohamed Abd Al-Moname Mohamed Abd Al-Halim :: Publications:

Title:
Effect of the Gas Pressure and the Charging Voltage on the Plasma Current Density Distribution in Conical Z Pinch Plasma Thruster
Authors: H. A. Eltayeb M. E. Abdel-kader, M. A. Abd Al-Halim, A. M. Shagar
Year: 2015
Keywords: Conical dischargeZ-pinchPin-ring dischargePlasma currentPinch timePinch duration
Journal: Journal of Fusion Energy
Volume: 34
Issue: 2
Pages: 238
Publisher: Springer Link
Local/International: International
Paper Link:
Full paper Not Available
Supplementary materials Not Available
Abstract:

Plasma current density is measured inside the chamber of a conical z-pinch device using helium as the working gas. The gas pressure and the charging voltage are the major factors affecting the magnitude of the plasma current, pinching time, and the pinch duration. Calculations are carried out at different radial positions between the pin electrode and the chamber wall. The experimental results show that the current density reaches a maximum value of about 8.7 kA/cm2 above the pin electrode for 7 kV charging voltage and 1 Torr pressure, and this value decreases toward the chamber wall. The gas pressure has a significant effect on the current density at radial position of 0.5 cm from the pin indicating that the plasma could not be confined to a radius less than that. This result is confirmed by the recorded plasma current signal in which one peak only is recorded at the pin and two or three are recorded near the wall as a result of sequent compression and expansion. The experimental results show that a time of 2–2.5 μs is needed for the pinch to occur. Increasing the discharge voltage decreases both pinch time and the pinch duration due to the faster confinement process.

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