To Snake or Not to Snake in the Planar Swift–Hohenberg Equation

Avitabile, Daniele; Lloyd, David J. B.; Burke, John; Knobloch, Edgar; Sandstede, Björn

doi:10.1137/100782747

Cited by 105 publications

(144 citation statements)

References 40 publications

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“…Recent work on these systems has identified the presence of spatially localized convection in the form of structures that have been called convectons [5][6][7][8][9][10] and the presence of such structures has been related to the phenomenon of homoclinic snaking that has been extensively studied in the context of model systems such as the Swift-Hohenberg equation. [11][12][13][14] These new states consist of a finite number of rolls embedded in a background conduction state and are located in the so-called snaking or pinning region in parameter space. Within this region the convectons lie on a pair of intertwined branches: in systems with midplane symmetry these consist of states of odd and even parity; when this symmetry is absent the branches consist of even parity states with either downflow or upflow in their center.…”

Section: Introductionmentioning

confidence: 99%

Localized rotating convection with no-slip boundary conditions

et al. 2013

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Localized patches of stationary convection embedded in a background conduction state are called convectons. Multiple states of this type have recently been found in two-dimensional Boussinesq convection in a horizontal fluid layer with stress-free boundary conditions at top and bottom, and rotating about the vertical. The convectons differ in their lengths and in the strength of the self-generated shear within which they are embedded, and exhibit slanted snaking. We use homotopic continuation of the boundary conditions to show that similar structures exist in the presence of no-slip boundary conditions at the top and bottom of the layer and show that such structures exhibit standard snaking. The homotopic continuation allows us to study the transformation from slanted snaking characteristic of systems with a conserved quantity, here the zonal momentum, to standard snaking characteristic of systems with no conserved quantity. C 2013 AIP Publishing LLC. [http://dx

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Section: Introductionmentioning

confidence: 99%

Localized rotating convection with no-slip boundary conditions

et al. 2013

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“…States of this type expand abruptly in the extended direction near a special point in parameter space corresponding to the formation of a pair of heteroclinic connections between two different fixed points in a spatial dynamics view of the system. 26 This point, variously referred to as the nonsnaking 35 or protosnaking 36 point plays the role of a Maxwell point in systems, like the Swift-Hohenberg equation (1), with gradient dynamics. If the spatial eigenvalues of one of the fixed points are complex the resulting behavior may be termed collapsed snaking.…”

Section: Discussionmentioning

confidence: 99%

Nonsnaking doubly diffusive convectons and the twist instability

2013

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Doubly diffusive convection in a three-dimensional horizontally extended domain with a square cross section in the vertical is considered. The fluid motion is driven by horizontal temperature and concentration differences in the transverse direction. When the buoyancy ratio N = −1 and the Rayleigh number is increased the conduction state loses stability to a subcritical, almost two-dimensional roll structure localized in the longitudinal direction. This structure exhibits abrupt growth in length near a particular value of the Rayleigh number but does not snake. Prior to this filling transition the structure becomes unstable to a secondary twist instability generating a pair of stationary, spatially localized zigzag states. In contrast to the primary branch these states snake as they grow in extent and eventually fill the whole domain. The origin of the twist instability and the properties of the resulting localized structures are investigated for both periodic and no-slip boundary conditions in the extended direction. C 2013 AIP Publishing LLC. [http://dx

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“…The snaking structure has e.g. been studied a lot in the one dimensional [16] and the two dimensional [17] SwiftHohenberg equation, which is a convenient and generic model system to study fundamental properties of the arising dynamics.…”

Section: Introductionmentioning

confidence: 99%

“…Notice that the higher the energy of the solution, the larger the number of convection cells. Often the two snaking branches are also interconnected through a number of unstable branches, and a ladder like pattern emerges [17].…”

Section: Introductionmentioning

confidence: 99%

“…In many respects this is quite surprising, since non-linear oscillators with subcritical Hopf bifurcations, often coupled to neighbouring oscillators of the same type into chains or arrays, are actually very common models for a number of systems from engineering vibrations. And also the appearance of bi-or multi-stability, which is obviously at the core of the phenomenon [13][16] [17], is well established in many of these engineering systems. Moreover, the emergence of spatially localised vibration states in structural dynamics is also a well known observational fact: e.g.…”

Section: Introductionmentioning

confidence: 99%

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Snaking bifurcations in a self-excited oscillator chain with cyclic symmetry

Papangelo

Grolet

Salles

et al. 2017

Communications in Nonlinear Science and Numerical Simulation

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Snaking bifurcations in a chain of mechanical oscillators are studied. The individual oscillators are weakly nonlinear and subject to self-excitation and subcritical Hopf-bifurcations with some parameter ranges yielding bistability. When the oscillators are coupled to their neighbours, snaking bifurcations result, corresponding to localised vibration states. The snaking patterns do seem to be more complex than in previously studied continuous systems, comprising a plethora of isolated branches and also a large number of similar but not identical states, originating from the weak coupling of the phases of the individual oscillators.

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To Snake or Not to Snake in the Planar Swift–Hohenberg Equation

Cited by 105 publications

References 40 publications

Localized rotating convection with no-slip boundary conditions

Localized rotating convection with no-slip boundary conditions

Nonsnaking doubly diffusive convectons and the twist instability

Snaking bifurcations in a self-excited oscillator chain with cyclic symmetry

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