MULTITEMPERATURE VIBRATIONAL AND CHEMICAL KINETICS IN AIR FLOWS BEHIND SHOCK WAVES

In this paper chemical and vibrational relaxation of the five component air mixture behind shock waves is studied numerically on the basis of the three-temperature and one-temperature kinetic theory approaches. The influence of vibrational nonequilibrium as well as anharmonicity effects on the rates of exchange chemical reactions and macroscopic flow parameters in relaxation zone behind shock waves is estimated for different Mach numbers.

колебательная и химическая кинетика, ударная волна, трехтемпературное приближение, обменные химические реакции, пятикомпонентная воздушная смесь, vibrational and chemical kinetics, shock wave, three-temperature approach, exchange chemical reactions, five components air mixture

1. Ступоченко Е.В., Лосев С.А., Осипов А.И. Релаксационные процессы в ударных волнах. М.: Наука, 1965. 484 с.

2. R. Brun (Ed.), High Temperature Phenomena in Shock Waves, Springer-Verlag, Berlin Heidelberg, 2012. 337 p.

3. Физико-химические процессы в газовой динамике / под редакцией Черного Г.Г. и Лосева С.А. / М.:Науч. мир. 1995. Т. 1., 2002. Т. 2.

4. Нагнибеда Е.А., Кустова Е.В. Кинетическая теория процессов переноса и релаксации в потоках неравновесных реагирующих газов. СПб.: Изд-во СПб ун-та, 2003 272 с.

5. Kunova O.V., Nagnibeda E.A. State-to-state description of reacting air flows behind shock waves // Chemical Physics, 2014. Vol. 441, pp. 66-76

6. Chikhaoui A., Dudon J.P., Geneys S., Kustova E.V., Nagnibeda E.A. Multitemperature kinetic model for heat transfer in reacting gas mixture // Phys. Fluids. 2000. Vol.12. № 1. pp. 220 - 230.

7. Kunova O.V., Nagnibeda E.A., Sharafutdinov I.Z. Vibrational-chemical coupling in air flows behind shock waves // 21st International Shock Interaction Symposium. Book of Proceedings. 2014. pp. 179-184

8. Bourdon A., Annaloro J., Bultel A., Capitelli M., Colonna G., Guy A., Magin T.E., Munafó A., Perrin M.Y. and Pietanza L.D. Reduction of State-to-State to Macroscopic Models for Hypersonics // The Open Plasma Physics Journal, 2014, № 7. pp. 60 - 75.

9. Colonna G., Armenise I., Bruno D., Capitelli M. Reduction of state-to-state kinetics to macroscopic models in hypersonic flows // Journal of Thermophysics and Heat Transfer, Vol. 20, N 3, 2006, pp. 477 - 486.

10. Colonna G., Pietanza L.D., Capitelli M. Reduced two-level approach for air kinetics in recombination regime // AIP Conference Proceedings, Vol. 1333, N 1, 2011, pp. 1365 - 1370.

11. Гордиец Б.Ф., Осипов А.И., Шелепин Л.А. Кинетические процессы в газах и молекулярные лазеры. М.: Наука, 1980. 512 с.

12. Treanor C.E., Rich J.W., Rehm R.G. Vibrational relaxation of anharmonic oscillators with exchange dominated collisions. // J. Chem. Phys. 1968. Vol. 48. pp. 1798 - 1807.

13. Герцберг Г. Спектры и строение двухатомных молекул. М.: Изд-во иностр. лит., 1949. 403 с.

14. Capitelli M., Armenise I., Gorse C. State -to-state approach in the kinetics of air components under re-entry conditions. J. Thermophys. Heat Transfer. 1997. Vol. 11. N 4. pp. 570 - 578.

15. Capitelli M., Ferreira C.M., Gordiets B.F., Osipov A.I. Plasma kinetics in atmospheric gases. Berlin: Springer-Verlag, 2000

16. Test Case 2: Definition of shock tunnel test cases for gas radiation prediction in a planetary atmosphere, in: Proceedings of the International Workshop on Radiation of High Temperature Gases in Atmospheric Entry, Part II. Porquerolles, France (ESA SP-583, April 2004), p. 139

17. Warnatz J., Riedel U., Schmidt R. Different levels of air dissociation chemistry and its coupling with flow models. In: Advanced in Hypersonic Flows, Vol.2: Modeling Hypersonic Flows. Birkhäuser, Boston, 1992. pp. 67 - 103.