Dispersive optical soliton solutions to the truncated time M-fractional paraxial wave equation with its stability analysis

被引：1

作者：

Ahmad J. ^{[1
]}

Noor K. ^{[1
]}

Akram S. ^{[1
]}

机构：

[1] Department of Mathematics, Faculty of Science, University of Gujrat, Gujrat

来源：

Optical and Quantum Electronics | 2024年 / 56卷 / 05期

关键词：

Analytic solutions; Improved F-expansion method; Modified exponent function method; Paraxial wave equation; Stability analysis; Traveling wave; Truncated time M-fractional derivative;

D O I：

10.1007/s11082-024-06663-6

中图分类号：

学科分类号：

摘要：

This article investigates the truncated time M-fractional paraxial wave equation. This model is frequently used to depict the activation of waves in utterly different physical frameworks, such as quantum mechanics and optics. Two trustworthy methodologies, the improved F-expansion and modified exponent function method, are used to obtain the different soliton solutions to the truncated time M-fractional paraxial wave equation. The obtained solutions offer a valuable understanding of the underlying physical events. Discussion is also had over the equation’s modulation instability, which confirms the given equation is stable. Several graphical charts, including 2D, 3D, density, and contour, are produced using symbolic software. These visual representations have a significant positive impact on qualitative evaluations of diverse natural occurrences. The evaluated findings showed that the approaches employed in this work to obtain inclusive and standard solutions are efficient and speedier in computing, they will be beneficial in addressing more difficult higher order nonlinear perturbed truncated time M-fractional models. © The Author(s), under exclusive licence to Springer Science+Business Media, LLC, part of Springer Nature 2024.

引用

共 54 条

[11] Bilal M., Haris H., Waheed A., Faheem M., The analysis of exact solitons solutions in monomode optical fibers to the generalized nonlinear Schrödinger system by the compatible techniques, Int. J. Math. Comput. Sci, 1, 2, pp. 149-170, (2023)
[12] Golmankhaneh A.K., Welch K., Serpa C., Fuzzification of Fractal Calculus, P. E, (2023)
[13] Hussain A., Ali H., Zaman F., Abbas N., New closed form solutions of some nonlinear pseudo-parabolic models via a new extended direct algebraic method, Int. J. Math. Comput. Sci., (2023)
[14] Ibrahim R.W., Jalab H.A., Karim F.K., Alabdulkreem E., Ayub M.N., A medical image enhancement based on generalized fractional partial differential equations classes, Quant. Imaging Med. Surg, 12, (2022)
[15] Ilhan E., Kiymaz I.O., (2020) Generalization of truncated M-fractional derivative and applications to fractional differential equations, Appl. Math. Nonlinear Sci, 5, 1, pp. 171-188, (2023)
[16] Ismael H.F., Baskonus H.M., Bulut H., Gao W., Instability modulation and novel optical soliton solutions to the Gerdjikov-Ivanov equation with M-fractional, Opt. Quantum Electron, 55, (2021)
[17] Jin T., Yang X., Monotonicity theorem for the uncertain fractional differential equation and application to the uncertain financial market, Math. Comput. Simul, 190, pp. 203-221, (2021)
[18] Khater M.M., Computational and numerical wave solutions of the Caudrey–Dodd–Gibbon equation, Heliyon, 9, 2, (2023)
[19] Khater M.M., Soliton propagation under diffusive and nonlinear effects in physical systems
[20] (1+ 1)–dimensional MNW integrable equation, Phys. Lett. A, (2023)

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