Novel Explosive and Super Fractional Nonlinear Schrödinger Structures

H. G. Abdelwahed; A. F. Alsarhan; E. K. El-Shewy; Mahmoud A.E. Abdelrahman

doi:10.1155/2023/9996773

Novel Explosive and Super Fractional Nonlinear Schrödinger Structures

H. G. Abdelwahed, A. F. Alsarhan, E. K. El-Shewy, Mahmoud A.E. Abdelrahman

Physics

Research output: Contribution to journal › Article › peer-review

6 Scopus citations

Abstract

The fractional nonlinear Schrödinger equation solutions have been investigated via fraction space-time derivative sense. We applied the unified technique for this model to extract new structures of waves. The fractional property structures were obtained from the model in form of hyperbolic, soliton, shock, explosive, superperiodic, and trigonometric structures. It was found that increasing fractal factors produces a change in the phase and wave frequency of propagating nonlinear waves. The physical models that explain tidal energy generation are crucial to the development of contemporary green power systems. The parametric description for wave characteristics in this process is created by the solution of nonlinear equations. The obtained solutions are applicable in new communications, energy applications, fractional quantum modes, and in science and complex phenomena in astrophysics. Finally, the proposed technique can be implemented for further fractional physical models.

Original language	English
Article number	9996773
Journal	Journal of Mathematics
Volume	2023
DOIs	https://doi.org/10.1155/2023/9996773
State	Published - 2023

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title = "Novel Explosive and Super Fractional Nonlinear Schr{\"o}dinger Structures",

abstract = "The fractional nonlinear Schr{\"o}dinger equation solutions have been investigated via fraction space-time derivative sense. We applied the unified technique for this model to extract new structures of waves. The fractional property structures were obtained from the model in form of hyperbolic, soliton, shock, explosive, superperiodic, and trigonometric structures. It was found that increasing fractal factors produces a change in the phase and wave frequency of propagating nonlinear waves. The physical models that explain tidal energy generation are crucial to the development of contemporary green power systems. The parametric description for wave characteristics in this process is created by the solution of nonlinear equations. The obtained solutions are applicable in new communications, energy applications, fractional quantum modes, and in science and complex phenomena in astrophysics. Finally, the proposed technique can be implemented for further fractional physical models.",

author = "Abdelwahed, \{H. G.\} and Alsarhan, \{A. F.\} and El-Shewy, \{E. K.\} and Abdelrahman, \{Mahmoud A.E.\}",

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journal = "Journal of Mathematics",

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AU - Abdelwahed, H. G.

AU - Alsarhan, A. F.

AU - El-Shewy, E. K.

AU - Abdelrahman, Mahmoud A.E.

PY - 2023

Y1 - 2023

N2 - The fractional nonlinear Schrödinger equation solutions have been investigated via fraction space-time derivative sense. We applied the unified technique for this model to extract new structures of waves. The fractional property structures were obtained from the model in form of hyperbolic, soliton, shock, explosive, superperiodic, and trigonometric structures. It was found that increasing fractal factors produces a change in the phase and wave frequency of propagating nonlinear waves. The physical models that explain tidal energy generation are crucial to the development of contemporary green power systems. The parametric description for wave characteristics in this process is created by the solution of nonlinear equations. The obtained solutions are applicable in new communications, energy applications, fractional quantum modes, and in science and complex phenomena in astrophysics. Finally, the proposed technique can be implemented for further fractional physical models.

AB - The fractional nonlinear Schrödinger equation solutions have been investigated via fraction space-time derivative sense. We applied the unified technique for this model to extract new structures of waves. The fractional property structures were obtained from the model in form of hyperbolic, soliton, shock, explosive, superperiodic, and trigonometric structures. It was found that increasing fractal factors produces a change in the phase and wave frequency of propagating nonlinear waves. The physical models that explain tidal energy generation are crucial to the development of contemporary green power systems. The parametric description for wave characteristics in this process is created by the solution of nonlinear equations. The obtained solutions are applicable in new communications, energy applications, fractional quantum modes, and in science and complex phenomena in astrophysics. Finally, the proposed technique can be implemented for further fractional physical models.

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VL - 2023

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JF - Journal of Mathematics

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Novel Explosive and Super Fractional Nonlinear Schrödinger Structures

Abstract

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