Plasma Current Sheath Dynamics and Energy Dissipation in a Low-Energy Plasma Focus Device
Arab Journal of Nuclear Sciences and Applications • 2020
Publication Information
Authors
A. A. Lashin1, T. M. Allam1, H. A. El-sayed1, K. M. Ahmed1, *, S. A. Ward2, M. A. Abouelatta2 and H. M. Soliman1
Keywords
Plasma focus, plasma current sheath, focus action, energy dissipation
Journal
Arab Journal of Nuclear Sciences and Applications
Publisher
Arab Journal of Nuclear Sciences and Applications
Volume
Not Available
Issue
ISSN 1110-0451 Web site: ajnsa.journals.ekb.eg (ESNSA)
Pages
Not Available
publication.type
Local
Paper Link
Not Available
Supplementary Materials
Sayed Abo-Elsood Sayed Ward_papers ahmed lashein ph.d.pdf
Abstract
The present study reports the measurements of plasma current sheath (PCS) dynamics, the energy dissipation processes, and the plasma focus (PF) electrical characteristics, particularly during the axial phase discharge in a Mather-type PF device (EAEA-PF1) energized with a 30 µF capacitor bank charged with 8, 10 and 12 kV. All these investigations carried out under discharge conditions where the optimal PF action is achieved. At each charging voltage (Vch), 8 kV, 10 kV and 12 kV, the optimal PF action is studied at different argon gas pressures (P) ranging from 0.4 to 1.2 Torr. The results show that the best PF is formed at Vch = 8 kV and P = 0.6 Torr, Vch = 10 kV and P = 0.8 Torr, and Vch = 12 kV and P = 0.8 Torr. The implosion velocity (Vz) results of PCS show that the maximum value of Vz (4.48 cm/µs) occurs at the end of the axial phase (i.e., at the coaxial electrode muzzle), which is detected at Vch = 12 kV and P = 0.8 Torr. Moreover, a less inefficient snowplow action is observed under these discharge conditions. The energy dissipation process data indicate that at Vch = 12 kV and P = 0.8 Torr, the ratio between the total energy dissipation and the input energy has a maximum value of ≅ 90%, and the minimum residual energy left on the condenser bank (175.39 J) is also achieved under these discharge conditions.
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