Competing resonances in spatially forced pattern-forming systems

Mau, Yair; Haim, Lev; Hagberg, Aric; Meron, Ehud

doi:10.1103/physreve.88.032917

Cited by 23 publications

(18 citation statements)

References 45 publications

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“…For slightly larger ε, theory predicts that the amplitude of one of these modes dominates the other and an oblique roll pattern emerges. The same behaviour was also found in simulations of the parametrically forced Swift-Hohenberg equation by Manor, Hagberg & Meron (2008) and Mau et al (2013). Possible reasons for the discrepancy will be discussed in § 4.…”

Section: Cross-roll (Cr) Patternssupporting

confidence: 72%

Resonance patterns in spatially forced Rayleigh–Bénard convection

2014

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We report on the influence of a quasi-one-dimensional periodic forcing on the pattern selection process in Rayleigh-Bénard convection (RBC). The forcing was introduced by a lithographically fabricated periodic texture on the bottom plate. We study the convection patterns as a function of the Rayleigh number (Ra) and the dimensionless forcing wavenumber (q f ). For small Ra, convection takes the form of straight parallel rolls that are locked to the underlying forcing pattern. With increasing Ra, these rolls give way to more complex patterns, due to a secondary instability. The forcing wavenumber q f was varied in the experiment over the range of 0.6q c < q f < 1.4q c , with q c being the critical wavenumber of the unforced system. We investigate the stability of straight rolls as a function of q f and report patterns that arise due to a secondary instability.

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Section: Cross-roll (Cr) Patternssupporting

confidence: 72%

Resonance patterns in spatially forced Rayleigh–Bénard convection

2014

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“…(14). Whether the 3 : 1 resonance is a good representative of higher resonances in its basic properties-a subcritical pattern forming instability and multiplicity of n translationally symmetric, stable even-phase solutions-remains an open question.…”

Section: Discussionmentioning

confidence: 99%

“…We note that Eq. (14) reduces to known equations when the inversion symmetry is reintroduced (λ = 0) [13,14].…”

Section: Derivation Of the Amplitude Equationmentioning

confidence: 99%

“…(1) can be obtained by studying constant solutions of the amplitude Eq. (14) or its equivalent form Eq. (17).…”

Section: Resonant Periodic Solutionsmentioning

confidence: 99%

“…The SH equation can be viewed as the simplest model that captures a nonuniform stationary instability, i.e., an instability that renders a uniform state unstable and gives rise to a stationary periodic pattern. In a series of recent works we used the SH equation to study spatial parametric forcing as a means of stabilizing patterns, extending their existence range, controlling their wavenumbers and amplitudes, and creating new patterns [11][12][13][14].…”

Section: Introductionmentioning

confidence: 99%

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Spatial forcing of pattern-forming systems that lack inversion symmetry

2014

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The entrainment of periodic patterns to spatially periodic parametric forcing is studied. Using a weak nonlinear analysis of a simple pattern formation model we study the resonant responses of one-dimensional systems that lack inversion symmetry. Focusing on the first three n:1 resonances, in which the system adjusts its wavenumber to one nth of the forcing wavenumber, we delineate commonalities and differences among the resonances. Surprisingly, we find that all resonances show multiplicity of stable phase states, including the 1:1 resonance. The phase states in the 2:1 and 3:1 resonances, however, differ from those in the 1:1 resonance in remaining symmetric even when the inversion symmetry is broken. This is because of the existence of a discrete translation symmetry in the forced system. As a consequence, the 2:1 and 3:1 resonances show stationary phase fronts and patterns, whereas phase fronts within the 1:1 resonance are propagating and phase patterns are transients. In addition, we find substantial differences between the 2:1 resonance and the other two resonances. While the pattern forming instability in the 2:1 resonance is supercritical, in the 1:1 and 3:1 resonances it is subcritical, and while the inversion asymmetry extends the ranges of resonant solutions in the 1:1 and 3:1 resonances, it has no effect on the 2:1 resonance range. We conclude by discussing a few open questions.

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