New wave solutions of an integrable dispersive wave equation with a fractional time derivative arising in ocean engineering models

Authors

  • Ali Tozar Hatay Mustafa Kemal University
  • Ali Kurt hatay Mustafa Kemal University
  • Orkun Tasbozan Hatay Mustafa Kemal university

Keywords:

Conformable fractional derivative, New extended direct algebraic method, Camassa-Holm equation, Shallow water waves, Wave Solutions.

Abstract

It is complicated to analyze many events taking place in nature. Idealization which can be defined as neglecting the nonlinear parts of the event can be used to facilitate a deterministic perspective to our understanding of the nature. However, this approximation usually doesn't work when interactions are fully nonlinear. Oceans are the best examples of the systems where interactions are nonlinear. In order to evaluate such systems, unique differential equations are needed. Camassa-Holm equation is one of the most attractive unique differential equation due to its integrability. In this paper, the new wave solutions of  fractional Camassa-Holm equation that generally used as a powerful tool in computer simulation of the water waves in shallow water, coastal and harbor models are obtained by using the new extended direct algebraic method. A completely new thirty-six solutions were obtained and were graphically represented. These solutions can be inspiring for future researchers.

Author Biographies

Ali Tozar, Hatay Mustafa Kemal University

Department of Physics

Ali Kurt, hatay Mustafa Kemal University

Department of Mathematics

Orkun Tasbozan, Hatay Mustafa Kemal university

Department of Mathematics

References

References

Birse, M.C., Soliton models for nuclear physics. Progress in Particle and Nuclear Physics, 1990. 25: p. 1-80.

Ovid'Ko, I.A. and A.E. Romanov, TOPOLOGICAL EXCITATIONS (DEFECTS, SOLITONS, TEXTURES, FRUSTRATIONS) IN CONDENSED MEDIA. Physica Status Solidi a-Applications and Materials Science, 1987. 104(1): p. 13-45.

Mitschke, F., C. Mahnke, and A. Hause, Soliton Content of Fiber-Optic Light Pulses. Applied Sciences-Basel, 2017. 7(6): p. 22.

Qin, C.Y., et al., On breather waves, rogue waves and solitary waves to a generalized (2+1)-dimensional Camassa-Holm-Kadomtsev-Petviashvili equation. Communications in Nonlinear Science and Numerical Simulation, 2018. 62: p. 378-385.

Marathe, A. and R. Govindarajan, Nonlinear Dynamical Systems, Their Stability, and Chaos. Applied Mechanics Reviews, 2014. 66(2): p. 16.

Pelinovsky, D.E. and Y.A. Stepanyants, Helical solitons in vector modified Korteweg-de Vries equations. Physics Letters A, 2018. 382(44): p. 3165-3171.

Guo, D. and S.F. Tian, Stability analysis, soliton waves, rogue waves and interaction phenomena for the (3+1)-dimensional generalized Kadomtsev-Petviashvili equation. Modern Physics Letters B, 2018. 32(28): p. 11.

Huang, Y.H., et al., The rogue wave of the nonlinear Schrodinger equation with self-consistent sources. Modern Physics Letters B, 2018. 32(30): p. 14.

Crisan, D. and D.D. Holm, Wave breaking for the Stochastic Camassa-Holm equation. Physica D-Nonlinear Phenomena, 2018. 376: p. 138-143.

Constantin, A. and D. Lannes, The Hydrodynamical Relevance of the Camassa–Holm and Degasperis–Procesi Equations. Archive for Rational Mechanics and Analysis, 2009. 192(1): p. 165-186.

Constantin, A. and R.I. Ivanov, On an integrable two-component Camassa–Holm shallow water system. Physics Letters A, 2008. 372(48): p. 7129-7132.

Eckhardt, J., The Inverse Spectral Transform for the Conservative Camassa-Holm Flow with Decaying Initial Data. Archive for Rational Mechanics and Analysis, 2017. 224(1): p. 21-52.

Chang, X.K. and J. Szmigielski, Lax Integrability and the Peakon Problem for the Modified Camassa-Holm Equation. Communications in Mathematical Physics, 2018. 358(1): p. 295-341.

Wang, F. and F.Q. Li, Continuity properties of the data-to-solution map for the two-component higher order Camassa-Holm system. Nonlinear Analysis-Real World Applications, 2019. 45: p. 866-876.

Matsuno, Y., Multisoliton solutions of the two-component Camassa-Holm system and their reductions. Journal of Physics a-Mathematical and Theoretical, 2017. 50(34): p. 28.

Luo, T., Stability of the Camassa-Holm Multi-peakons in the Dynamics of a Shallow-Water-Type System. Journal of Dynamics and Differential Equations, 2018. 30(4): p. 1627-1659.

Zhang, J.E. and Y.S. Li, Bidirectional solitons on water. Physical Review E, 2003. 67(1): p. 8.

Parker, A., Wave dynamics for peaked solitons of the Camassa–Holm equation. Chaos, Solitons & Fractals, 2008. 35(2): p. 220-237.

Fokas, A.S. and B. Fuchssteiner, On the structure of symplectic operators and hereditary symmetries. Lettere al Nuovo Cimento (1971-1985), 1980. 28(8): p. 299-303.

Kazolea, M. and M. Ricchiuto, On wave breaking for Boussinesq-type models. Ocean Modelling, 2018. 123: p. 16-39.

Xiao, H., Y.L. Young, and J.H. Prevost, Parametric study of breaking solitary wave induced liquefaction of coastal sandy slopes. Ocean Engineering, 2010. 37(17-18): p. 1546-1553.

Miller, K.S. and B. Ross, An Introduction to the Fractional Calculus and Fractional Differential Equations. 1993: Wiley.

Kilbas, A.A.A., H.M. Srivastava, and J.J. Trujillo, Theory And Applications of Fractional Differential Equations. 2006: Elsevier Science & Tech.

Podlubny, I., Fractional Differential Equations: An Introduction to Fractional Derivatives, Fractional Differential Equations, to Methods of Their Solution and Some of Their Applications. 1998: Elsevier Science.

Khalil, R., et al., A new definition of fractional derivative. Journal of Computational and Applied Mathematics, 2014. 264: p. 65-70.

Abdeljawad, T., On conformable fractional calculus. Journal of Computational and Applied Mathematics, 2015. 279: p. 57-66.

Rezazadeh, H., F.S. Khodadad, and J. Manafian, New structure for exact solutions of nonlinear time fractional Sharma-Tasso-Olver equation via conformable fractional derivative. Applications and Applied Mathematics-an International Journal, 2017. 12(1): p. 405-414.

Downloads

Published

06-03-2020