Symmetry of periodic traveling waves for nonlocal dispersive equations

TL;DR

This paper establishes symmetry properties of periodic traveling wave solutions for a broad class of nonlocal dispersive equations, including non-smooth solutions, using a reflection criterion and maximum principle techniques.

Contribution

It introduces a reflection criterion that ensures symmetry of solutions without requiring monotonicity, applicable to non-smooth waves with peaks or cusps.

Findings

Symmetry of solutions is guaranteed under specific symbol conditions.

The method applies to both smooth and non-smooth wave profiles.

The approach relaxes classical assumptions like monotonicity between crest and trough.

Abstract

Of concern is the a priori symmetry of traveling wave solutions for a general class of nonlocal dispersive equations \[ u_t +(u^2 +Lu)_x =0, \] where $L$ is a Fourier multiplier operator with symbol $m$. Our analysis includes both homogeneous and inhomogeneous symbols. We characterize a class of symbols $m$ guaranteeing that periodic traveling wave solutions are symmetric under a mild assumption on the wave profile. Particularly, instead of considering waves with a unique crest and trough per period or a monotone structure near troughs as classically imposed in the water wave problem, we formulate a reflection criterion, which allows to affirm the symmetry of periodic traveling waves. The reflection criterion weakens the assumption of monotonicity between trough and crest and enables to treat a priori solutions with multiple crests of different sizes per period. Moreover, our result not only applies to smooth solutions, but also to traveling waves with a non-smooth structure such as peaks or cusps at a crest. The proof relies on a so-called touching lemma, which is related to a strong maximum principle for elliptic operators, and a weak form of the celebrated method of moving planes.