Inhomogeneous frozen states in the Swift-Hohenberg equation: hexagonal patterns vs. localized structures

We revisit the Swift-Hohenberg model for two-dimensional hexagonal patterns in the bistability region where hexagons coexist with the uniform quiescent state. We both analyze the law of motion of planar interfaces (separating hexagons and uniform regions), and the stability of localized structures....

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Bibliographic Details
Published in:arXiv.org 2003-06
Main Authors: Boyer, Denis, Mondragón-Palomino, Octavio
Format: Article
Language:English
Subjects:
Bistability
Crystal structure
Domains
Electrons
Hexagons
Interface stability
Motion stability
Parameter estimation
Plasma
Structural stability
Two dimensional models
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Summary:We revisit the Swift-Hohenberg model for two-dimensional hexagonal patterns in the bistability region where hexagons coexist with the uniform quiescent state. We both analyze the law of motion of planar interfaces (separating hexagons and uniform regions), and the stability of localized structures. Interfaces exhibit properties analogous to that of interfaces in crystals, such as faceting, grooving and activated growth or " melting". In the nonlinear regime, some spatially disordered heterogeneous configurations do not evolve in time. Frozen states are essentially composed of extended polygonal domains of hexagons with pinned interfaces, that may coexist with isolated localized structures randomly distributed in the quiescent background. Localized structures become metastable at the pinning/depinning transition of interfaces. In some region of the parameter space, localized structures shrink meanwhile interfaces are still pinned. The region where localized structures have an infinite life-time is relatively limited.
ISSN:2331-8422