Abstract:
To check the earlier proposed hypothesis on the considerable cluster effect and the ion-atom nonideality in saturated cesium vapors, a chemical model is proposed that accounts for the presence of neutral, positively, and negatively charged small-sized cluster ions and the main types of interatomic interactions. The partition sums of atoms, ions, and clusters are calculated as are the composition and pressure of cesium vapors on the binodal. It is shown that, on the saturation line, cesium vapor in the near-critical region consists mainly of atoms and a small admixture of molecules, whereas the charged component consists predominantly of Cs−, Cs+3, and Cs+2 ions whose amount is considerably lower than the amount of atoms. Interactions between charged particles and between the charged and neutral ones significantly influence the charge composition of vapors and weakly affect the equation of state and the composition of neutral component of vapors. The calculated compressibility and conductivity of the cesium vapor plasma are in good agreement with the experimental data for the near-critical isobars.
Citation:
A. L. Khomkin, A. S. Shumikhin, “Thermodynamic and transport properties of cesium vapors on binodal and in its vicinity”, TVT, 51:5 (2013), 663–669; High Temperature, 51:5 (2013), 594–600
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\by A.~L.~Khomkin, A.~S.~Shumikhin
\paper Thermodynamic and transport properties of cesium vapors on binodal and in its vicinity
\jour TVT
\yr 2013
\vol 51
\issue 5
\pages 663--669
\mathnet{http://mi.mathnet.ru/tvt127}
\crossref{https://doi.org/10.7868/S0040364413050116}
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\transl
\jour High Temperature
\yr 2013
\vol 51
\issue 5
\pages 594--600
\crossref{https://doi.org/10.1134/S0018151X13050118}
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Linking options:
https://www.mathnet.ru/eng/tvt127
https://www.mathnet.ru/eng/tvt/v51/i5/p663
This publication is cited in the following 10 articles:
A. L. Khomkin, A. S. Shumikhin, “Processes of Thermal and Cold Ionization of Metal Vapors in the Vicinity of the Critical Point of the Vapor–Liquid Phase Transition”, High Temp, 60:S3 (2022), S295
A. L. Khomkin, A. S. Shumikhin, “Supercritical fluid of metal vapor plasmas, rare gases, and excitons”, Phys. Usp., 64:11 (2021), 1125–1148
A. L. Khomkin, A. S. Shumikhin, “Protsessy termicheskoi i “kholodnoi” ionizatsii parov metallov v okrestnosti kriticheskoi tochki perekhoda par–zhidkost”, TVT, 59:6 (2021), 805–811
Khomkin A.L. Shumikhin A.S., “The Processes of Thermal and “Cold” Ionization in Caesium Vapours”, Contrib. Plasma Phys., 61:10, SI (2021), e202100072
Khomkin A.L., Shumikhin A.S., “Is the Atomic Metal Vapor a Dielectric State?”, Phys. Scr., 96:3 (2021), 035806
V F Lapshin, V Yu Florinsky, “Control of plasma spatial distribution in gas discharge lamps filled with alkali metal vapors”, J. Phys.: Conf. Ser., 2131:2 (2021), 022056
Baksht F.G., Lapshin V.F., “Modeling of the Plasma Waveguide on the Basis of the Pulse-Periodic High-Pressure Cesium Discharge”, Plasma Phys. Rep., 46:8 (2020), 846–849
Khomkin A.L. Shumikhin A.S., “Gaseous Metal and the Problem of Vapor-Liquid (Insulator-Metal) Transition in Metal Vapors”, J. Exp. Theor. Phys., 130:4 (2020), 602–609
A. L. Khomkin, A. S. Shumikhin, “Conductivity of metal vapors at the critical point”, J. Exp. Theor. Phys., 123:5 (2016), 891
M. A. Butlitskii, B. B. Zelener, B. V. Zelener, “About the Coulomb phase transition”, High Temperature, 53:2 (2015), 161–166
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