膜方程的全局近平面对称解

IF 2.8 1区数学 Q1 MATHEMATICS

Forum of Mathematics Pi Pub Date : 2019-03-08 DOI:10.1017/fmp.2020.10

L. Abbrescia, W. Wong

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引用次数: 11

摘要

我们证明了在足够小的紧支承扰动下，膜方程在空间维度$d\geqslant 3$上具有有限空间范围的任何简单平面行波解都是全局非线性稳定的，其中的小程度取决于扰动的支持大小以及初始行波剖面。该论点的主要新颖之处在于我们基于向量场的方法中缺乏高阶剥离。特别是，高阶能量(实际上，所有阶为$2$或更高的能量)可以随时间多项式地增长(但以一种可控的方式)。这与经典的全局稳定性论证相反，在经典的全局稳定性论证中，只有自举论证中使用的“上”阶能量呈现增长，并反映了背景行波解具有“无限能量”和摄动方程的系数不是渐近洛伦兹不变量的事实。尽管如此，我们可以通过仔细分析非线性相互作用并在方程中暴露某种“残余”零结构来证明$C^{2}$中的扰动收敛于零。

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GLOBAL NEARLY-PLANE-SYMMETRIC SOLUTIONS TO THE MEMBRANE EQUATION

We prove that any simple planar travelling wave solution to the membrane equation in spatial dimension $d\geqslant 3$ with bounded spatial extent is globally nonlinearly stable under sufficiently small compactly supported perturbations, where the smallness depends on the size of the support of the perturbation as well as on the initial travelling wave profile. The main novelty of the argument is the lack of higher order peeling in our vector-field-based method. In particular, the higher order energies (in fact, all energies at order $2$ or higher) are allowed to grow polynomially (but in a controlled way) in time. This is in contrast with classical global stability arguments, where only the ‘top’ order energies used in the bootstrap argument exhibit growth, and reflects the fact that the background travelling wave solution has ‘infinite energy’ and the coefficients of the perturbation equation are not asymptotically Lorentz invariant. Nonetheless, we can prove that the perturbation converges to zero in $C^{2}$ by carefully analysing the nonlinear interactions and exposing a certain ‘vestigial’ null structure in the equations.

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来源期刊

Forum of Mathematics Pi Mathematics-Statistics and Probability

CiteScore

3.50

自引率

0.00%

发文量

审稿时长

19 weeks

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