Optical soliton solutions: the evolution with changing fractional-order derivative in Biswas–Arshed and Schrödinger Kerr law equations

Optical soliton solutions: the evolution with changing fractional-order derivative in Biswas–Arshed and Schrödinger Kerr law equations

The space–time fractional Biswas–Arshed and Schrödinger Kerr law equations featuring beta derivative hold substantial application in nonlinear optics, optical solitons, ultrafast optical signal, nonlinear photonics, quantum optics, biophotonics, photonic crystals photonics, etc. In this study, a wid...

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Bibliographic Details
Published in:Optical and quantum electronics Vol. 56; no. 3
Main Authors: Asaduzzaman, Akbar, M. Ali
Format: Journal Article
Language:English
Published: New York Springer US 01-03-2024
Springer Nature B.V
Subjects:
Characterization and Evaluation of Materials
Communications systems
Computer Communication Networks
Electrical Engineering
Evolution
Fractional calculus
Lasers
Mathematical analysis
Nonlinear optics
Optical communication
Optical Devices
Optics
Parameters
Photonic crystals
Photonics
Physics
Physics and Astronomy
Quantum optics
Rational functions
Shape
Signal processing
Solitary waves
Waveforms
Schrödinger Kerr law equation
Beta derivative
Soliton solutions
Biswas–Arshed equation
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Summary:The space–time fractional Biswas–Arshed and Schrödinger Kerr law equations featuring beta derivative hold substantial application in nonlinear optics, optical solitons, ultrafast optical signal, nonlinear photonics, quantum optics, biophotonics, photonic crystals photonics, etc. In this study, a wide variety of geometric shape solitons have been established that include hyperbolic, exponential, trigonometric, and rational functions, as well as their assimilation to the considered equations, through the two-variable ( R ′ / R , 1 / R )-expansion approach. The implication of the fractional parameter μ on the wave shape has also been examined by depicting two-dimensional and three-dimensional plots for particular parameter values. The solitons include irregular periodic, pulse like, V-shaped, bell-shaped, positive periodic, asymptotic, general solitons, and some others. It is significant to note that the changes in the wave pattern result from the adjustments to substantive and auxiliary parameters. The outcomes demonstrate the efficiency, acceptability, and dependability of the ( R ′ / R , 1 / R )-expansion approach for obtaining solutions to the fractional-order evolution equations in the domains of engineering, technology, and sciences. It is evident from the graph that changing the value of μ results in a change in the shape of the soliton. The study explores how these equations change as fractional-order derivatives vary. Soliton solutions, which are stable, localized waveforms, are crucial in optical communication systems. Understanding their behavior under changing fractional-order derivatives is essential for advancing optical signal processing and communication technologies.
ISSN:0306-8919
1572-817X
DOI:10.1007/s11082-023-05955-7