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On the singular nature of shallow-water convergence of the intermediate long wave equation on the real line

Andreia Chapouto, Benjamin Harrop-Griffiths, Guopeng Li, Tadahiro Oh

Abstract

We investigate regularity properties of the solution map for the intermediate long wave equation (ILW) on the real line. More precisely, we study the scaled ILW which was shown to converge to the Korteweg-de Vries equation (KdV) in $L^2(\mathbb R)$ in the shallow-water limit in a recent work by the first, third, and fourth authors with T. Zhao (2025). By decomposing the dynamics into the low frequency part and the residual part, we show that, when the depth parameter is sufficiently small, the solution map for the low frequency part is analytic in $L^2(\mathbb R)$, while the solution map for the residual part fails to be $C^2$. Moreover, we establish shallow-water convergence in $L^2(\mathbb R)$ of the low frequency dynamics to KdV. This explains the mechanism of the regularity gain of the solution map in the shallow-water limit.

On the singular nature of shallow-water convergence of the intermediate long wave equation on the real line

Abstract

We investigate regularity properties of the solution map for the intermediate long wave equation (ILW) on the real line. More precisely, we study the scaled ILW which was shown to converge to the Korteweg-de Vries equation (KdV) in in the shallow-water limit in a recent work by the first, third, and fourth authors with T. Zhao (2025). By decomposing the dynamics into the low frequency part and the residual part, we show that, when the depth parameter is sufficiently small, the solution map for the low frequency part is analytic in , while the solution map for the residual part fails to be . Moreover, we establish shallow-water convergence in of the low frequency dynamics to KdV. This explains the mechanism of the regularity gain of the solution map in the shallow-water limit.
Paper Structure (9 sections, 7 theorems, 140 equations)

This paper contains 9 sections, 7 theorems, 140 equations.

Table of Contents

  1. Introduction
  2. Preliminaries
  3. Notations
  4. On the resonance functions
  5. Low frequency dynamics
  6. Proof of Theorem \ref{['THM:1']} (i)
  7. Shallow-water convergence of the low frequency dynamics
  8. On other frequency interactions
  9. Failure of $C^2$-regularity of the residual dynamics

Key Result

Theorem 1.1

(i) Let $0 \le \delta \le 1$ and $s \ge 0$. Then, given any $\phi \in H^s(\mathbb{R})$, there exists small $T = T(\|\phi\|_{H^s})> 0$, independent of $0 \le \delta \le 1$, such that the map, sending $\phi \in H^s(\mathbb{R})$ to the solution $v^\textup{low} \in C([0, T]; H^s(\mathbb{R}))$ to sILW2

Theorems & Definitions (19)

  • Theorem 1.1
  • Remark 1.2
  • Remark 1.3
  • Remark 1.4
  • Remark 1.5
  • Lemma 2.1
  • Lemma 2.2
  • proof
  • Lemma 3.1: low $\times$ low $\mapsto$ low
  • Remark 3.2
  • ...and 9 more