Micropteron traveling waves in diatomic Fermi–Pasta–Ulam–Tsingou lattices under the equal mass limit

https://doi.org/10.1016/j.physd.2020.132538Get rights and content
Under a Creative Commons license
open access

Highlights

  • The article studies traveling waves in diatomic FPUT lattices.

  • The traveling waves are constructed for mass ratios close to 1.

  • These traveling waves are micropterons.

  • A micropteron is the superposition of a solitary wave and a small periodic tail.

  • Many proofs hinge on Jost solutions for advance–delay differential equations.

Abstract

The diatomic Fermi–Pasta–Ulam–Tsingou (FPUT) lattice is an infinite chain of alternating particles connected by identical nonlinear springs. We prove the existence of micropteron traveling waves in the diatomic FPUT lattice in the limit as the ratio of the two alternating masses approaches 1, at which point the diatomic lattice reduces to the well-understood monatomic FPUT lattice. These are traveling waves whose profiles asymptote to a small periodic oscillation at infinity, instead of vanishing like the classical solitary wave. We produce these micropteron waves using a functional-analytic method, originally due to Beale, that was successfully deployed in the related long wave and small mass diatomic problems. Unlike the long wave and small mass problems, this equal mass problem is not singularly perturbed, and so the amplitude of the micropteron’s oscillation is not necessarily small beyond all orders (i.e., the traveling wave that we find is not necessarily a nanopteron). The central challenge of this equal mass problem hinges on a hidden solvability condition in the traveling wave equations, which manifests itself in the existence and fine properties of asymptotically sinusoidal solutions (Jost solutions) to an auxiliary advance–delay differential equation. The novelty compared to previous approaches is that this operator is neither a Fourier multiplier nor a small nonlocal perturbation of a classical differential operator. This causes fundamental technical obstructions, which we overcome by developing new functional-analytic techniques to uncover the asymptotic phase shifts of the Jost solutions.

Keywords

FPU
Nonlinear Hamiltonian lattice
Diatomic lattice
Generalized solitary wave
Nanopteron
Micropteron

Cited by (0)