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Published April 1966 | Published
Journal Article Open

Recombination, ionization, and nonequilibrium electrical conductivity in seeded plasmas

Abstract

New data are presented which provide direct experimental confirmation of the validity of a physical model which has been widely employed to predict the electrical conductivity of dense, two-temperature, seeded plasmas. Experimental measurements of electron temperature, and ionization and recombination rates are presented for partially ionized plasmas of potassium-seeded argon. Experimental conditions were chosen to cover those ranges of interest in connection with proposed magnetohydrodynamic energy conversion devices for which nonequilibrium electrical conductivity measurements have been previously reported, e.g., translational atom temperatures of about 2000°K, total atom densities near 10^(18)/cm^3, potassium densities of about 10^(16)/cm^3, electron densities from 10^(13)/cm^3 to 10^(15)/cm^3, and electron temperatures from 2200 to 3500°K. Measured values of electron-electron-ion recombination coefficients for potassium show good agreement with theoretical values based upon the Gryzinski classical inelastic-collision cross-section expressions. Observed ionization rates and relaxation characteristics appear to be adequately explained by a similar formulation for the ionization process.

Additional Information

© 1966 American Institute of Physics. Received 16 September 1965. Online Publication Date: 9 December 2004. This work was supported by the Air Force Office of Scientific Research primarily under Grant No. AF-AFOSR-160-63, and partially under Contract No. AF 49(638)-1346.

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