Polyatomic gases with dynamic pressure: Kinetic non-linear closure and the shock structure

• Published in: International journal of non-linear mechanics Vol. 92; pp. 160 - 175
• Main Authors: Pavić-Čolić, Milana, Madjarević, Damir, Simić, Srboljub
• Format: Journal Article
• Language: English
• Published: New York Elsevier Ltd 01.06.2017; Elsevier BV
• Subjects: Atoms & subatomic particles; Collision dynamics; Continuity (mathematics); Dynamic pressure; Entropy; Internal energy; Kinetic theory; Kinetic theory of gases; Kinetics; Maximum entropy; Polyatomic gases; Shock structure; Thermodynamics; 76L05; Polyatomic gases; 82D05; Kinetic theory of gases; 76P05; Shock structure; 82C40; Dynamic pressure
• ISSN: 0020-7462; 1878-5638
• DOI: 10.1016/j.ijnonlinmec.2017.04.008

This paper is concerned with the analysis of polyatomic gases within the framework of kinetic theory. Internal degrees of freedom are modelled using a single continuous variable corresponding to the molecular internal energy. The state of the gas is determined by the 6 fields—5 standard fields (mass density, velocity and temperature) and the dynamic pressure. Using the maximum entropy principle and the non-equilibrium entropy density, it is shown that dynamic pressure appears as a natural measure for deviation from equilibrium state. A proper collision cross section is constructed which obeys the micro-reversibility requirement. The non-linear source term in the balance law for dynamic pressure, and the entropy production rate, are determined using collision operator in the form which generalizes the known results obtained within the framework of extended thermodynamics. They are also compared with the results obtained using BGK approximation. For the proposed model the shock structure problem is thoroughly analyzed and discussed for different values of the parameters in the source term. •Polyatomic gases are treated within the framework of kinetic theory, using dynamic pressure as a non-equilibrium variable.•It is shown that dynamic pressure appears as a natural measure for deviation from equilibrium state.•A proper collision cross section is constructed which obeys the micro-reversibility requirement.•The non-linear source term and the entropy production are determined in kinetic framework, and compared with other models.•The shock structure problem is thoroughly analyzed and discussed for different values of the parameters in the source term.