KP solitons in shallow water

TL;DR

This paper surveys soliton solutions of the KP equation, classifies them via Grassmannians, explores their stability, and applies the theory to shallow water Mach reflection, supported by numerical and experimental evidence.

Contribution

It introduces a classification of KP solitons using Grassmannians and demonstrates their relevance to shallow water wave phenomena, including Mach reflection.

Findings

KP solitons are classified by totally non-negative Grassmannians.

Numerical simulations show initial waves can evolve into KP solitons.

KP theory accurately predicts Mach reflection phenomena with higher order corrections.

Abstract

The main purpose of the paper is to provide a survey of our recent studies on soliton solutions of the Kadomtsev-Petviashvili (KP) equation. The classification is based on the far-field patterns of the solutions which consist of a finite number of line-solitons. Each soliton solution is then defined by a point of the totally non-negative Grassmann variety which can be parametrized by a unique derangement of the symmetric group of permutations. Our study also includes certain numerical stability problems of those soliton solutions. Numerical simulations of the initial value problems indicate that certain class of initial waves asymptotically approach to these exact solutions of the KP equation. We then discuss an application of our theory to the Mach reflection problem in shallow water. This problem describes the resonant interaction of solitary waves appearing in the reflection of an obliquely incident wave onto a vertical wall, and it predicts an extra-ordinary four-fold amplification of the wave at the wall. There are several numerical studies confirming the prediction, but all indicate disagreements with the KP theory. Contrary to those previous numerical studies, we find that the KP theory actually provides an excellent model to describe the Mach reflection phenomena when the higher order corrections are included to the quasi-two dimensional approximation. We also present laboratory experiments of the Mach reflection recently carried out by Yeh and his colleagues, and show how precisely the KP theory predicts this wave behavior.