Treatment of the Thermal Nonequilibrium and Ionization Effects on the Refractive Index of a Reacting Gas: Atmospheric Air and Combustion Products

Treatment of the Thermal Nonequilibrium and Ionization Effects on the Refractive Index of a Reacting Gas: Atmospheric Air and Combustion Products

Using thermal nonequilibrium physicochemical kinetics models, which make it possible to numerically study the reacting gas flows with allowance for the processes of vibrational and electronic-translational relaxation and exchange, as well as the chemical and plasmachemical reactions, the profiles of...

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Bibliographic Details
Published in:Fluid dynamics Vol. 59; no. 4; pp. 957 - 972
Main Authors: Loukhovitski, B. I., Kadochnikov, I. N., Arsentiev, I. V., Sharipov, A. S.
Format: Journal Article
Language:English
Published: Moscow Pleiades Publishing 2024
Springer Nature B.V
Subjects:
Chemical reactions
Classical and Continuum Physics
Classical Mechanics
Combustion products
Dipole moments
Electrical properties
Engineering Fluid Dynamics
Fluid- and Aerodynamics
Gas flow
Heat treatment
Optical properties
Physics
Physics and Astronomy
Refractivity
Supersonic nozzles
Synthesis gas
electronic excitation
vibrational nonequilibrium
refractive index
ionization
Gladstone–Dale constant
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Summary:Using thermal nonequilibrium physicochemical kinetics models, which make it possible to numerically study the reacting gas flows with allowance for the processes of vibrational and electronic-translational relaxation and exchange, as well as the chemical and plasmachemical reactions, the profiles of the Gladstone–Dale constant and refractive index are calculated for two model problems: relaxation of the air behind the shock wave (SW) front and expansion of hydrogen and syngas combustion products in a supersonic nozzle. The required data on the electrical properties (polarizability and dipole moment) of the neutral and charged gas components in their ground and excited states are taken from the literature or estimated using recently developed analytical models. For each of the model gas-dynamic problems, the accuracy of various approximations when calculating the optical properties of a gas is analyzed.
ISSN:0015-4628
1573-8507
DOI:10.1134/S0015462824602614