Radiative tail of solitary waves in an extended Korteweg-de Vries equation

arXiv - PHYS - Pattern Formation and Solitons Pub Date : 2024-08-22 DOI:arxiv-2408.12356

Muneeb Mushtaq

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Abstract

We solve the fifth-order Korteweg-de Vries (fKdV) equation which is a modified KdV equation perturbed by a fifth-order derivative term multiplied by a small parameter $\epsilon^2$, with $0< \epsilon \ll 1$. Unlike the KdV equation, the stationary fKdV equation does not exhibit exactly localized 1-soliton solution, instead it allows a solution which has a well defined central core similar to that of the KdV 1-soliton solution, accompanied by extremely small oscillatory standing wave tails on both sides of the core. The amplitude of the standing wave tail oscillations is $\mathcal{O}(\exp(-1/\epsilon))$, i.e. it is beyond all orders small in perturbation theory. The analytical computation of the amplitude of these transcendentally small tail oscillations has been carried out up to $\mathcal{O}(\epsilon^5)$ order corrections by using the complex method of matched asymptotics. Also the long-standing discrepancy between the $\mathcal{O}(\epsilon^2)$ perturbative result of Grimshaw and Joshi (1995) and the numerical results of Boyd (1995) has been resolved. In addition to the stationary symmetric weakly localized solitary wave-like solutions, we analyzed the stationary asymmetric solutions of the fKdV equation which decay exponentially to zero on one side of the (slightly asymmetric) core and blows up to large negative values on other side of the core. The asymmetry is quantified by computing the third derivative of the solution at the origin which also turns out to be beyond all orders small in perturbation theory. The analytical computation of the third derivative of a function at the origin has also been carried out up to $\mathcal{O}(\epsilon^5)$ order corrections. We use the exponentially convergent pseudo-spectral method to solve the fKdV equation numerically. The analytical and the numerical results show remarkable agreement.

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扩展 Korteweg-de Vries 方程中孤波的辐射尾迹

我们求解了五阶 Korteweg-de Vries（fKdV）方程，它是由一个五阶导数项乘以一个小参数$\epsilon^2$（$0< \epsilon \ll 1$）扰动的改良 KdV 方程。与 KdV 方程不同，静止的 fKdV 方程并不表现出精确的局部 1-oliton解，相反，它的解具有与 KdV 1-oliton解类似的定义明确的中心核心，同时在核心两侧伴有极小的振荡驻波尾。驻波尾振荡的振幅是$\mathcal{O}(\exp(-1/\epsilon))$，也就是说，它超出了扰动理论中所有阶的小振幅。通过使用匹配渐近的复杂方法，我们已经分析计算了直至$\mathcal{O}(\epsilon^5)$阶校正的超越小尾振荡的振幅。同时，格里姆肖和乔希（1995）的$\mathcal{O}(\epsilon^2)$微扰结果与博伊德（1995）的数值结果之间长期存在的差异也得到了解决。除了静态对称弱局域孤波样解之外，我们还分析了 fKdV 方程的静态非对称解，这些解在（略微不对称的）核心的一侧呈指数衰减为零，而在核心的另一侧膨胀为大负值。通过计算解在原点的三次导数，可以量化这种不对称现象。原点处函数三阶导数的分析计算也已经进行到了$\mathcal{O}(\epsilon^5)$阶修正。我们使用指数收敛伪谱法数值求解 fKdV 方程。分析和数值结果显示了显著的一致性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - PHYS - Pattern Formation and Solitons

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