Dynamics of Different Nonlinearities to the Perturbed Nonlinear Schrödinger Equation via Solitary Wave Solutions with Numerical Simulation

Zafar, Asim; Raheel, Muhammad; Zafar, Muhammad Qasim; Nisar, Kottakkaran Sooppy; Osman, M. S.; Mohamed, Roshan Noor; Elfasakhany, Ashraf

doi:10.3390/fractalfract5040213

Cited by 29 publications

(5 citation statements)

References 40 publications

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“…Gepreel constructed exact soliton solutions by capitalizing multiple ansatz methods such as rational solitary wave method, q-deformed hyperbolic function, and q-deformed trigonometric function. A. Zafar et al investigated solitary wave solutions for the governing model by means of the Modified Extended tanh Expansion Method [32]. Our research manipulated this study to execute two approaches, new rational extended ShGEEM and the generalized y v -( ( )) exp -expansion method.…”

Section:  Results and Discussionmentioning

confidence: 99%

“…It also has numerous applications in mathematical finance, fluid dynamics, plasma physics, biochemistry, nuclear physics, superconductivity describing solitary wave propagation in piezoelectric semiconductors, condensed matter, solid-state physics characterizing the propagation of a heat pulse in a solid, and so on [36][37][38][39]. Consider the following dynamical model which is known as perturbed nonlinear Schrödinger [32], that can be used to describe some interesting (1+1)-dimensional waves of optics,…”

Section:  Introductionmentioning

confidence: 99%

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Diverse optical solitons to nonlinear perturbed Schrödinger equation with quadratic-cubic nonlinearity via two efficient approaches

Rehman¹,

Ahmad²

2023

Phys. Scr.

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In this study, the nonlinear perturbed Schrödinger equation(NPSE) with nonlinear terms as quadratic-cubic law nonlinearity media with the beta derivative is investigated and this investigated model is considered an icon in the field of optical fibers where it describes the wave function or state function of the optical system. Numerous solutions are extracted by engaging two novel schemes known as generalized $\exp(-\psi(\varpi))$-expansion method (GEEM) and rational extended sinh-Gordon equation expansion method (REShGEEM) in distinct forms such as bright, dark, singular and combinations of these solutions. In addition, plane wave, periodic and exponential solutions are also recovered. Using the computer application Wolfram Mathematica 11, the dynamic structure and physical characterization of some observed solutions are vividly depicted by sketching different plots. Comparing our new results with well-known literature is also given which justifies the novelty of this work. Obtained results will hold a significant place in the field of nonlinear optical fibers and suggest that the proposed methods are very influential and effective tools for solving more complex nonlinear partial differential equations in mathematical physics, engineering and nonlinear optics.

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Section:  Results and Discussionmentioning

confidence: 99%

Section:  Introductionmentioning

confidence: 99%

Diverse optical solitons to nonlinear perturbed Schrödinger equation with quadratic-cubic nonlinearity via two efficient approaches

Rehman¹,

Ahmad²

2023

Phys. Scr.

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“…Nonlinear fractional mathematical models (NLFMMs) are broadly implemented to express lots of significant phenomena and nonlinear dynamic applications in applied mathematics, mathematical physics, engineering, signal processing, electromagnetics, communications, acoustics, genetic algorithms, viscoelasticity, robotics, electrochemistry, transport systems, material science, finance, image processing, stochastic dynamical systems, biology, plasma physics, chemistry, nonlinear control theory, and so many. In accordance with determining the exact answers of NLFMMs, countless influential and well-organized schemes have been presented and industrialized, such as the variation of ðG ′ /GÞ-expansion scheme [1], modified ðG ′ /GÞ-expansion technique [2][3][4][5], the first integral technique [6], gener-alized Kudryashov technique [7], fractional subequation scheme [8,9], improved fractional sub-equation scheme [10], generalized exponential rational task scheme [11], novel extended direct algebraic method [12], Sine-Gordon expansion technique [13], subequation scheme [14], Kudryashov technique [15], Jacobi elliptic task scheme [16], exp-task scheme [17], the Jacobi elliptic ansatz method [18], natural transform method [19], fractional iteration algorithm [20,21], the unified method [22], the hyperbolic and exponential ansatz method [23], ð1/G′Þ-expansion scheme [24], modified decomposition method [25], the quintic B-spline approaches [26], an efficient semianalytical algorithm [27], the Jacobi elliptic function expansion (JEFE) method [28], the Lie symmetry technique [29], Hirota's simple method [30,31], the modified extended tanh expansion method [32], exponential finite difference method …”

Section: Introductionmentioning

confidence: 99%

Regarding on the Results for the Fractional Clannish Random Walker’s Parabolic Equation and the Nonlinear Fractional Cahn-Allen Equation

Alam

İlhan

Uddin

et al. 2022

Advances in Mathematical Physics

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In this research, the Ψ , Φ -expansion scheme has been implemented for the exact solutions of the fractional Clannish Random Walker’s parabolic (FCRWP) equation and the nonlinear fractional Cahn-Allen (NFCA) equation. Some new solutions of the FCRWP equation and the NFCA equation have been obtained by using this method. The diverse variety of exact outcomes such as intersection between rough wave and kinky soliton wave profiles, intersection between lump wave and kinky soliton wave profiles, soliton wave profiles, kink wave profiles, intersection between lump wave and periodic wave profiles, intersection between rough wave and periodic wave profiles, periodic wave profiles, and kink wave profiles are taken. Comparing our developed answers and that got in previously written research papers presents the novelty of our investigation. The above techniques could also be employed to get exact solutions for other fractional nonlinear models in physics, applied mathematics, and engineering.

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“…It is necessary to find the solutions of the nonlinear evolution equations. Many mathematicians and researchers have found Lump solutions, soliton solutions, breather solutions and interaction solutions [26][27][28][29][30][31][32][33][34]. The methods of looking for solutions are used widely, including Darboux transformation method [35,36], the ( ¢ G G)-expansion method [37][38][39], inverse scattering transformation method [40,41], Hirota bilinear method [42][43][44][45][46][47], variable separation method [48][49][50][51][52] and so on.…”

Section: Introductionmentioning

confidence: 99%

Superposition solutions to a (3+1)-dimensional variable-coefficient Sharma-Tasso-Olver-Like equation

Fan¹,

Bao²

2022

Phys. Scr.

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In this paper, the superposition solutions of (3+1)-dimensional variable-coefficient Sharma-Tasso-Olver-Like(vcSTOL) equation are studied. The equation can illustrate various difficult sciences areas. Due to the wide application, it is very important to find the exact solutions of it. By introducing transformation, the equation is transformed into bilinear form. We use variable separation method and trial function method to obtain the superposition solutions of the equation containing different functions and forms. The images are drawn with the help of symbolic computing system Mathematica, and the properties of the solutions are analyzed. The analysis shows that different functions will affect the overall shape of waves, including the interaction between waves, the size, the direction and the number of waves, which can get more new phenomena. To our knowledge, those types of superposition solutions of (3+1)-dimensional vcSTOL equation mentioned in our work by variable separation method have not been reported before. Furthermore, we add the square terms to the expansion function, so that the obtained solutions have the characteristics of Lump solution, which has not been done in the previous literatures.

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Dynamics of Different Nonlinearities to the Perturbed Nonlinear Schrödinger Equation via Solitary Wave Solutions with Numerical Simulation

Cited by 29 publications

References 40 publications

Diverse optical solitons to nonlinear perturbed Schrödinger equation with quadratic-cubic nonlinearity via two efficient approaches

Diverse optical solitons to nonlinear perturbed Schrödinger equation with quadratic-cubic nonlinearity via two efficient approaches

Regarding on the Results for the Fractional Clannish Random Walker’s Parabolic Equation and the Nonlinear Fractional Cahn-Allen Equation

Superposition solutions to a (3+1)-dimensional variable-coefficient Sharma-Tasso-Olver-Like equation

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