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Auteurs principaux: Aiki, Masashi, Higaki, Mitsuo
Format: Preprint
Publié: 2026
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Accès en ligne:https://arxiv.org/abs/2604.15655
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author Aiki, Masashi
Higaki, Mitsuo
author_facet Aiki, Masashi
Higaki, Mitsuo
contents This paper investigates the dynamics of closed vortex filaments in $\R^3$ governed by the Localized Induction Equation. Recently, Aiki and Higaki (2026) established the nonlinear orbital stability of circular vortex filaments under asymmetric perturbations, while identifying Lyapunov instability due to the linear growth of translation modes. Motivated by this result, we prove the existence of a family of closed solutions, which we call axial screw motions, that bifurcate from a circular filament. These solutions remain uniformly close to the orbit of the circle, but drift secularly away from the reference motion because their translation speed along the symmetry axis differs from that of the circular filament. In particular, they provide explicit non-trivial perturbations that satisfy orbital-stability estimates while failing Lyapunov stability, thereby realizing the gap between orbital stability and Lyapunov stability near the circular filament.
format Preprint
id arxiv_https___arxiv_org_abs_2604_15655
institution arXiv
publishDate 2026
record_format arxiv
spellingShingle Lyapunov Unstable Motion Bifurcating from a Circular Vortex Filament
Aiki, Masashi
Higaki, Mitsuo
Analysis of PDEs
This paper investigates the dynamics of closed vortex filaments in $\R^3$ governed by the Localized Induction Equation. Recently, Aiki and Higaki (2026) established the nonlinear orbital stability of circular vortex filaments under asymmetric perturbations, while identifying Lyapunov instability due to the linear growth of translation modes. Motivated by this result, we prove the existence of a family of closed solutions, which we call axial screw motions, that bifurcate from a circular filament. These solutions remain uniformly close to the orbit of the circle, but drift secularly away from the reference motion because their translation speed along the symmetry axis differs from that of the circular filament. In particular, they provide explicit non-trivial perturbations that satisfy orbital-stability estimates while failing Lyapunov stability, thereby realizing the gap between orbital stability and Lyapunov stability near the circular filament.
title Lyapunov Unstable Motion Bifurcating from a Circular Vortex Filament
topic Analysis of PDEs
url https://arxiv.org/abs/2604.15655