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Dynamics of One-Dimensional Motion of a Gas Under the Influence of Monochromatic Radiation

  • Dig Vijay Tanwar [1] ; P. K. Sahu [2]
    1. [1] Graphic Era Deemed to be University
    2. [2] Government Shyama Prasad Mukharjee College
  • Localización: Qualitative theory of dynamical systems, ISSN 1575-5460, Vol. 22, Nº 2, 2023
  • Idioma: inglés
  • Enlaces
  • Resumen
    • The concern with the dispersion of shock waves in perfect gas in the context of monochromatic radiation is mentioned in this manuscript. The system of Hyperbolic nonlinear partial differential equations (NLPDEs) is used to address this issue. In order to study aforementioned equations, invariance under Lie symmetry analysis is performed. Therefore, commutative relations, symmetry groups and adjoint relations are established. The optimal system of one dimensional sub-algebra is also found by utilising invariant functions. We attempted to discover the possible exact solution using symmetry reductions as per the optimal system as well as a concise study on the characteristics of the various solutions provided. We have thus identified few new exact solutions containing several arbitrary constants. To analyze the physical structures, some of the obtained exact solution are described with graphical representations. The results typically assist to investigate wave interactions in various novel localised structures and models.

  • Referencias bibliográficas
    • 1. Hydon, P.E.: Symmetry Methods for Differential Equations: A Beginner’s Guide. Cambridge University Press (2000)
    • 2. Bluman, G.W., Cole, J.D.: Similarity Methods for Differential Equations. Springer, New York (1974)
    • 3. Stephani, H.: Differential Equations: Their Solution using Symmetries. Cambridge University Press (1989)
    • 4. Ibragimov, N.K., Ibragimov, N.K.: Elementary Lie Group Analysis and Ordinary Differential Equations. Wiley, New York (1999)
    • 5. Olver, P.J.: Applications of Lie Groups to Differential Equations. Springer, New York (1993)
    • 6. Hu, X., Li, Y., Chen, Y.: A direct algorithm of one-dimensional optimal system for the group invariant solutions. J. Math. Phys. 56, 053504...
    • 7. Chou, K.S., Li, G.X.: A note on optimal systems for the heat equation. J. Math. Anal. Appl. 261, 741–751 (2001)
    • 8. Kumar, M., Tanwar, D.V., Kumar, R.: On closed form solutions of (2 + 1)-breaking soliton system by similarity transformations method....
    • 9. Kumar, M., Tanwar, D.V., Kumar, R.: On Lie symmetries and soliton solutions of (2 +1)-dimensional Bogoyavlenskii equations. Nonlinear...
    • 10. Kumar, M., Tanwar, D.V.: On Lie symmetries and invariant solutions of (2 + 1)-dimensional Gardner equation. Commun. Nonlinear Sci....
    • 11. Kumar, M., Tanwar, D.V.: Lie symmetry reductions and dynamics of solitary wave solutions of breaking soliton equation. Int. J. Geom. Methods...
    • 12. Kumar, M., Tanwar, D.V.: On some invariant solutions of (2 + 1)-dimensional Korteweg-de Vries equations. Comput. Math. Appl. 76, 2535–2548...
    • 13. Kumar, M., Tanwar, D.V.: Lie symmetries and invariant solutions of (2 + 1)-dimensional breaking soliton equation. Pramana—J. Phys....
    • 14. Tanwar, D.V., Wazwaz, A.M.: Lie symmetries and dynamics of exact solutions of dissipative Zabolotskaya–Khokhlov equation in nonlinear...
    • 15. Tanwar, D.V.: Optimal system, symmetry reductions and group-invariant solutions of (2 + 1)- dimensional ZK-BBM equation. Phys. Scr....
    • 16. Kumar, R., Verma, R.S.: Dynamics of some new solutions to the coupled DSW equations traveling horizontally on the seabed. J. Ocean Eng....
    • 17. Kumar, R., Verma, R.S.: Dynamics of invariant solutions of mKdV-ZK arising in a homogeneous magnetised plasma. J. Ocean Eng. Sci. (2022)....
    • 18. Kumar, R., Kumar, A.: Dynamical behavior of similarity solutions of CKOEs with conservation law. Appl. Math. Comput. 422, 126976 (2022)
    • 19. Kumar, R., Verma, R.S.: Optimal subalgebra of GKP by using Killing form, Conservation Law and some more solutions. Int. J. Appl. Comput....
    • 20. Khudyakov, V.M.: The self-similar problem of the motion of a gas under the action of monochromatic radiation. Sovit Phys. Dokl. (trans....
    • 21. Zedan, H.A.: Applications of the group of equations of the one-dimensional motion of a gas under the influence of monochromatic radiation....
    • 22. Zheltukhin, A.N.: A family of exact solutions of the equations of the one-dimensional motion of a gas under the influence of monochromatic...
    • 23. Nath, O., Takhar, H.S.: Propagation of cylindrical shock waves under the action of monochromatic radiation. Astrophys. Sp. Sci. 166, 35–39...
    • 24. Nath, O., Takhar, H.S.: Spherical MHD shock waves under the action of monochromatic radiation. Astrophys. Sp. Sci. 202, 355–362 (1993)
    • 25. Nath, G., Sahu, P.K.: Similarity solution for the flow behind a cylindrical shock wave in a rotational axisymmetric gas with magnetic...
    • 26. Sahu, P.K.: Similarity solution for a spherical shock wave in a non-ideal gas under the influence of gravitational field and monochromatic...
    • 27. Sharma, K., Arora, R.: Similarity solutions for strong shock waves in non-ideal magnetogasdynamics under the effect of monochromatic radiation....
    • 28. Sahu, P.K.: Flow behind the magnetogasdynamical cylindrical shock wave in rotating non-ideal dusty gas with monochromatic radiation. Plasma...
    • 29. Nath, G., Devi, A.: Magnetogasdynamic shock wave propagation using the method of group invariance in rotating medium with the flux of...
    • 30. Sahu, P.K.: Analysis of magnetogasdynamic spherical shock wave in dusty real gas with gravitational field and monochromatic radiation....
    • 31. Nath, G.: Cylindrical shock wave propagation in a self-gravitating rotational axisymmetric perfect gas under the influence of azimuthal...
    • 32. Sahu, P.K.: Similarity solution for one dimensional motion of a magnetized self-gravitating gas with variable density under the absorption...

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