VIBRATIONAL-VIBRATIONAL ENERGY TRANSFER BETWEEN THE MODES OF DIATOMIC MOLECULES FOR SIMULATING NONEQUILIBRIUM GAS FLOWS

VIBRATIONAL-VIBRATIONAL ENERGY TRANSFER BETWEEN THE MODES OF DIATOMIC MOLECULES FOR SIMULATING NONEQUILIBRIUM GAS FLOWS

Implementation of the Candler model of vibrational-vibrational energy transfer between diatomic molecules in an inelastic collision is discussed. An example of oxygen O 2  and nitrogen N 2  interaction is used to analyze the method of simple iterations, the Newton method, the method of bisection, an...

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Veröffentlicht in:Journal of applied mechanics and technical physics 2023-08, Vol.64 (4), p.728-736
1. Verfasser: Shoev, G. V.
Format: Artikel
Sprache:eng
Schlagworte:
Applications of Mathematics
Classical and Continuum Physics
Classical Mechanics
Diatomic molecules
Energy distribution
Energy transfer
Fluid- and Aerodynamics
Gas flow
Inelastic collisions
Mathematical Modeling and Industrial Mathematics
Mechanical Engineering
Newton methods
Physics
Physics and Astronomy
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Zusammenfassung:Implementation of the Candler model of vibrational-vibrational energy transfer between diatomic molecules in an inelastic collision is discussed. An example of oxygen O 2  and nitrogen N 2  interaction is used to analyze the method of simple iterations, the Newton method, the method of bisection, and the approximate formula for calculating the equilibrium vibrational temperature, which is necessary in the Candler model. The method recommended for simulations is the Newton method or bisection. The model of vibrational-vibrational energy transfer is tested by examples of zero-dimensional vibrational relaxation, the flow around a cylinder, and the flow in a wedge-shaped nozzle. It is demonstrated that vibrational-vibrational energy transfer affects the distribution of vibrational temperatures.
ISSN:0021-8944
1573-8620
DOI:10.1134/S002189442304020X