Resonant phase-shift and global smoothing of the periodic Korteweg-de   Vries in low regularity settings

Seungly Oh

arXiv:1206.3898·math.AP·June 19, 2012

Resonant phase-shift and global smoothing of the periodic Korteweg-de Vries in low regularity settings

Seungly Oh

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TL;DR

This paper demonstrates a smoothing effect for low-regularity solutions of the periodic KdV equation by employing a resonant phase-shift, revealing near full derivative smoothing in a global-in-time setting.

Contribution

It introduces a novel resonant phase-shift technique that achieves near full derivative smoothing for low-regularity solutions of the periodic KdV equation.

Findings

01

Solutions gain near full derivative smoothing in low regularity spaces.

02

The resonant phase-shift operator effectively shifts Fourier support.

03

Normal form method is used to establish the smoothing result.

Abstract

We show a smoothing effect of near full derivative for low-regularity global-in-time solutions of the periodic Korteweg-de Vries (KdV) equation. The smoothing is given by slightly shifting the space-time Fourier support of the nonlinear solution, which we call \emph{resonant phase-shift}. More precisely, we show that $[S u] (t) - e^{- t \partial_{x}^{3}} u (0) \in H^{- s + 1 -}$ where $u (0) \in H^{- s}$ for $0 \leq s < 1/2$ where $S$ is the resonant phase-shift operator described below. We use the normal form method to obtain the result.

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Taxonomy

TopicsAdvanced Mathematical Physics Problems · Nonlinear Waves and Solitons · Nonlinear Photonic Systems