Investigating innovative optical solitons for a (3+1)- dimensional nonlinear Schrödinger’s equation under the influences of 4th-order dispersive and parabolic law of nonlinearities

Q3 Physics and Astronomy Results in Optics Pub Date : 2024-10-16 DOI:10.1016/j.rio.2024.100754
Abeer S. Khalifa , Hamdy M. Ahmed , Niveen M. Badra , Wafaa B. Rabie , Homan Emadifar
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Abstract

This study tackles a nonlinear Schrödinger’s equation in three dimensions, using three dispersive components of fourth order, often resulting in pure-quartic solitons. Pure-quartic bullets are known to deviate from conventional solitons due to their balance of fourth-order dispersion and nonlinearity. As bright and dark optically modulated bullets, we derive many solutions. Experiments on bullet transmission using optical nanofibers can benefit from the solutions found. Our creative solutions are produced by implementing the well-known scheme which is the improved modified extended tanh-function scheme. We find novel kinds of solutions (dark, bright, singular solitons, exponential, singular periodic, Weierstrass elliptic doubly periodic solutions, and Jacobi elliptic functions) that make their originality for the problem at hand evident by using the previously described approach. Contour plots and 2D and 3D visualizations in Wolfram Mathematica software are used to show how the well-furnished results propagate for various values of the necessary free parameters. The results demonstrate the computational processes’ precise, well-informed, and efficient nature. Through their integration with representational computations, they may be applied to increasingly complex phenomena. This work constitutes a major advancement in our comprehension of the intricate and erratic behavior of this mathematical model.
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研究四阶色散和抛物线非线性规律影响下 (3+1)- 维非线性薛定谔方程的创新光孤子
本研究利用三个四阶色散分量来处理三维非线性薛定谔方程,通常会产生纯方波孤子。众所周知,纯方波由于其四阶色散和非线性的平衡而偏离了传统的孤子。作为明暗光调制子弹,我们推导出许多解决方案。使用纳米光纤进行的子弹传输实验可以从找到的解决方案中获益。我们创造性的解决方案是通过实施著名的改进型扩展 tanh 函数方案而产生的。我们发现了一些新的解法(暗解、亮解、奇异孤子解、指数解、奇异周期解、魏尔斯特拉斯椭圆双周期解以及雅可比椭圆函数),这些解法的独创性通过使用之前描述的方法得到了体现。利用 Wolfram Mathematica 软件中的等高线图和二维及三维可视化功能,展示了所提供的结果如何在不同的必要自由参数值下传播。这些结果证明了计算过程的精确性、知情性和高效性。通过与表征计算的整合,它们可以应用于日益复杂的现象。这项工作是我们在理解这一数学模型复杂多变的行为方面取得的重大进展。
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来源期刊
Results in Optics
Results in Optics Physics and Astronomy-Atomic and Molecular Physics, and Optics
CiteScore
2.50
自引率
0.00%
发文量
115
审稿时长
71 days
期刊最新文献
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