Long Time Asymptotic Behavior for the Nonlocal mKdV Equation in Solitonic Space–Time Regions

IF 0.9 3区数学 Q3 MATHEMATICS, APPLIED

Mathematical Physics, Analysis and Geometry Pub Date : 2023-01-28 DOI:10.1007/s11040-023-09445-w

Xuan Zhou, Engui Fan

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引用次数: 1

Abstract

We study the long time asymptotic behavior for the Cauchy problem of an integrable real nonlocal mKdV equation with nonzero initial data in the solitonic regions

$$\begin{aligned}&q_t(x,t)-6\sigma q(x,t)q(-x,-t)q_{x}(x,t)+q_{xxx}(x,t)=0, \\&\quad q(x,0)=q_{0}(x),\ \ \lim _{x\rightarrow \pm \infty } q_{0}(x)=q_{\pm }, \end{aligned}$$

where $|q_{\pm }|=1$ and $q_{+}=\delta q_{-}$, $\sigma \delta =-1$. In our previous article, we have obtained long time asymptotics for the nonlocal mKdV equation in the solitonic region $-6<\xi <6$ with $\xi =\frac{x}{t}$. In this paper, we give the asymptotic expansion of the solution q(x, t) for other solitonic regions $\xi <-6$ and $\xi >6$. Based on the Riemann–Hilbert formulation of the Cauchy problem, further using the ${\bar{\partial }}$ steepest descent method, we derive different long time asymptotic expansions of the solution q(x, t) in above two different space-time solitonic regions. In the region $\xi <-6$, phase function $\theta (z)$ has four stationary phase points on the ${\mathbb {R}}$. Correspondingly, q(x, t) can be characterized with an ${\mathcal {N}}(\Lambda )$-soliton on discrete spectrum, the leading order term on continuous spectrum and an residual error term, which are affected by a function $\textrm{Im}\nu (\zeta _i)$. In the region $\xi >6$, phase function $\theta (z)$ has four stationary phase points on $i{\mathbb {R}}$, the corresponding asymptotic approximations can be characterized with an ${\mathcal {N}}(\Lambda )$-soliton with diverse residual error order ${\mathcal {O}}(t^{-1})$.

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孤子时空区域中非局部mKdV方程的长时间渐近行为

本文研究了具有非零初始数据的可积实非局部mKdV方程在孤子区域$$\begin{aligned}&q_t(x,t)-6\sigma q(x,t)q(-x,-t)q_{x}(x,t)+q_{xxx}(x,t)=0, \\&\quad q(x,0)=q_{0}(x),\ \ \lim _{x\rightarrow \pm \infty } q_{0}(x)=q_{\pm }, \end{aligned}$$ ($|q_{\pm }|=1$和$q_{+}=\delta q_{-}$, $\sigma \delta =-1$)中的Cauchy问题的长时间渐近性。在之前的文章中，我们用$\xi =\frac{x}{t}$得到了孤子区域$-6<\xi <6$中非局域mKdV方程的长时间渐近性。本文给出了其它孤子区域$\xi <-6$和$\xi >6$解q(x, t)的渐近展开式。基于柯西问题的Riemann-Hilbert公式，进一步利用${\bar{\partial }}$最陡下降法，我们在上述两个不同的时空孤子区域中导出了解q(x, t)的不同长时间渐近展开式。在$\xi <-6$区域，相函数$\theta (z)$在${\mathbb {R}}$上有四个固定相点。相应地，q(x, t)可以用离散谱上的${\mathcal {N}}(\Lambda )$ -孤子、连续谱上的首阶项和残差项来表征，它们受一个函数$\textrm{Im}\nu (\zeta _i)$的影响。在$\xi >6$区域中，相函数$\theta (z)$在$i{\mathbb {R}}$上有四个平稳相点，对应的渐近近似可以用一个残差阶不同的${\mathcal {N}}(\Lambda )$ -孤子表示${\mathcal {O}}(t^{-1})$。

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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来源期刊

Mathematical Physics, Analysis and Geometry 数学-物理：数学物理

CiteScore

2.10

自引率

0.00%

发文量

审稿时长

>12 weeks

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