Study of Luminous Emission from a Coaxial Plasma Discharge Device in the Presence of External Transverse Magnetic Field

The experimental investigations in this paper are focused on the study of luminous radiation emission from coaxial plasma discharge device and the effect of applied transverse magnetic field B sub( tr) on it. The experiment was done in (1.5 KJ - 10 KV) coaxial plasma discharge device. The discharge...

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Bibliographic Details
Published in:Dian li yu neng yuan 2011-09, Vol.3 (4), p.444-449
Main Authors: Allam, Tarek M., El-Sayed, Hanaa A., Soliman, Hanaa M.
Format: Article
Language:English
Subjects:
Coiling
Devices
Diagnostic systems
Discharge
Electrodes
Emission analysis
Magnetic fields
Magnetic induction
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Summary:The experimental investigations in this paper are focused on the study of luminous radiation emission from coaxial plasma discharge device and the effect of applied transverse magnetic field B sub( tr) on it. The experiment was done in (1.5 KJ - 10 KV) coaxial plasma discharge device. The discharge is operated in Nitrogen gas at pressures from 1 to 2.2 torr. Helmholtz magnetic coils are placed outside the coaxial electrodes with its axis at a distance = 3 cm from the coaxial electrodes muzzle, then B sub( tr) with a maximum induction approximately 0.85 T is ap-plied perpendicularly to the expanded plasma from the coaxial electrodes muzzle. The diagnostics used in the measurements include a Rogowsky coil and a photomultiplier tube equipped with light collimator. The experimental results showed that the maximum intensity of luminous radiation is detected at axial distance (side view) z = 8 cm and gas pressure, P = 2.2 torr. It also showed that the maximum value of axial luminous plasma zone velocity = 2.383 10 super( 6) cm/s at z = 11 cm and P = 1.4 torr. In mode of presence of external B sub( tr), the investigations have shown that, at P = 1.4 torr the maximum intensity of luminous radiation (detected at end-view position) is reduced by 17%, the full width at half maximum, FWHM of luminous radiation signal is increased by 40 times, while the luminous radiation signal is delayed by t sub( a) = 438 mu s. In two modes of op-eration t sub( a) and FWHM have approximately a minimum values at P = 1.4 torr.
ISSN:1949-243X
1947-3818
1947-3818
DOI:10.4236/epe.2011.34055