The Cauchy problem for the Degasperis-Procesi Equation: Painlev\'e Asymptotics in Transition Zones

TL;DR

This paper analyzes the long-time behavior of solutions to the Degasperis-Procesi equation, revealing Painlevé II asymptotics in transition zones between different wave regions using advanced Riemann-Hilbert techniques.

Contribution

It derives the leading order solution in transition zones, extending previous asymptotic results with Painlevé II asymptotics via a novel double scaling limit approach.

Findings

Painlevé II asymptotics describe transition zones

Extended asymptotic analysis to new regions

Applied $ar ext{d}$-steepest descent and double scaling techniques

Abstract

The Degasperis-Procesi (DP) equation \begin{align} &u_t-u_{txx}+3\kappa u_x+4uu_x=3u_x u_{xx}+uu_{xxx}, \nonumber \end{align} serving as an asymptotic approximation for the unidirectional propagation of shallow water waves, is an integrable model of the Camassa-Holm type and admits a $3\times3$ matrix Lax pair. In our previous work, we obtained the long-time asymptotics of the solution $u(x,t)$ to the Cauchy problem for the DP equation in the solitonic region $\{(x,t): \xi>3 \} \cup \{(x,t): \xi<-\frac{3}{8} \}$ and the solitonless region $\{(x,t): -\frac{3}{8}<\xi< 0 \} \cup \{(x,t): 0\leq \xi <3 \}$ where $\xi:=\frac{x}{t}$. In this paper, we derive the leading order approximation to the solution $u(x,t)$ in terms of the solution for the Painlev\'{e} \uppercase\expandafter{\romannumeral2} equation in two transition zones $\left|\xi+\frac{3}{8}\right|t^{2/3}<C$ and $\left|\xi -3\right|t^{2/3}<C$ with $C>0$ lying between the solitonic region and solitonless region. Our results are established by performing the $\bar \partial$-generalization of the Deift-Zhou nonlinear steepest descent method and applying a double scaling limit technique to an associated vector Riemann-Hilbert problem.