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Spectroscopic measurements of electron temperature and electron density in electron beam plasma generator based on collisional radiative model
Date
2007-01-01
Author
Goktas, H.
Demir, A.
Kacar, E.
Hegazy, H.
Turan, Raşit
Oke, G.
Seyhan, A.
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The current work describes a spectroscopic method for determining the electron temperature and electron density in an electron beam generator using argon spectral lines based on a collisional radiative model. Neutral and first-ionized Ar lines emitted from the electron beam generator are studied experimentally. A collisional radiative code was developed to simulate the Ar (I) and Ar (II) spectral emission and to compare the results with the experimental data for electron density and temperature determination. At lines and excited level densities were calculated by solving rate equations using the Gauss elimination method. The argon spectrum is recorded experimentally by superposing two discharges, namely a low pressure DC glow discharge and a high current pulsed discharge. Spectral lines between 350 nm and 950 nm were recorded using an integrated signal technique on a charge-coupled device. Electron temperature is determined by the relative intensity ratio method of two spectral lines. The relative intensity ratios of each peak are compared in a specific pressure range at various values, and good correlation is reported.
Subject Keywords
Analytical Chemistry
,
Spectroscopy
,
Atomic and Molecular Physics, and Optics
URI
https://hdl.handle.net/11511/41090
Journal
SPECTROSCOPY LETTERS
DOI
https://doi.org/10.1080/00387010600934469
Collections
Department of Physics, Article
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H. Goktas et al., “Spectroscopic measurements of electron temperature and electron density in electron beam plasma generator based on collisional radiative model,”
SPECTROSCOPY LETTERS
, pp. 183–192, 2007, Accessed: 00, 2020. [Online]. Available: https://hdl.handle.net/11511/41090.