Large-order asymptotics for multiple-pole solitons of the focusing nonlinear Schr\"odinger equation

TL;DR

This paper investigates the large-order behavior of multiple-pole solitons in the focusing nonlinear Schrödinger equation, revealing semiclassical patterns, exact boundary regions, and connections to Painlevé-III hierarchy functions.

Contribution

It provides a rigorous asymptotic analysis of high-order solitons, including exact boundary characterization and convergence to Painlevé-III hierarchy functions.

Findings

Exact boundary of quiescent regions computed.

Asymptotic limit of solitons in quiescent regions proven to be zero.

Scaled neighborhoods of the peak converge to Painlevé-III hierarchy functions.

Abstract

We analyze the large-$n$ behavior of soliton solutions of the integrable focusing nonlinear Schr\"odinger equation with associated spectral data consisting of a single pair of conjugate poles of order $2n$. Starting from the zero background, we generate multiple-pole solitons by $n$-fold application of Darboux transformations. The resulting functions are encoded in a Riemann-Hilbert problem using the robust inverse-scattering transform method recently introduced by Bilman and Miller. For moderate values of $n$ we solve the Riemann-Hilbert problem exactly. With appropriate scaling, the resulting plots of exact solutions reveal semiclassical-type behavior, including regions with high-frequency modulated waves and quiescent regions. We compute the boundary of the quiescent regions exactly and use the nonlinear steepest-descent method to prove the asymptotic limit of the solitons is zero in these regions. Finally, we study the behavior of the solitons in a scaled neighborhood of the central peak with amplitude proportional to $n$. We prove that in a local scaling the solitons converge to functions satisfying the second member of the Painlev\'e-III hierarchy in the sense of Sakka. This function is a generalization of a function recently identified by Suleimanov in the context of geometric optics and by Bilman, Ling, and Miller in the context of rogue wave solutions to the focusing nonlinear Schr\"odinger equation.