Probability of the Emergence of Helical Precipitation Patterns in the Wake of Reaction-Diffusion Fronts

Thomas, Shibi; Lagzi, István; Molnár, Ferenc; Rácz, Zoltán

doi:10.1103/physrevlett.110.078303

Cited by 50 publications

(69 citation statements)

References 30 publications

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“…More precisely, we are interested in systems that exhibit stable or metastable ordered states, such as stripes, or spots arranged in hexagonal lattices. Examples of such systems arise for example in di‐block copolymers , phase‐field models , and other phase separative systems , as well as in phyllotaxis , and reaction–diffusion systems . Throughout, we will focus on a paradigmatic model, the Swift–Hohenberg equation

u_{t} = - {(1 + Δ)}^{2} u + μ u - u^{3},

where

u = u (t, x, y) \in R

false(x, y false) \in {double-struckR}^{2}

t \in R

, subscripts denote partial derivatives, and

Δ u = u_{x x} + u_{y y}

.…”

Section: Introductionmentioning

confidence: 99%

Pattern‐forming fronts in a Swift–Hohenberg equation with directional quenching — parallel and oblique stripes

Goh

Scheel

2018

J. London Math. Soc.

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We study the effect of domain growth on the orientation of striped phases in a Swift–Hohenberg equation. Domain growth is encoded in a step‐like parameter dependence that allows stripe formation in a half plane, and suppresses patterns in the complement, while the boundary of the pattern‐forming region is propagating with fixed normal velocity. We construct front solutions that leave behind stripes in the pattern‐forming region that are parallel to or at a small oblique angle to the boundary. Technically, the construction of stripe formation parallel to the boundary relies on ill‐posed, infinite‐dimensional spatial dynamics. Stripes forming at a small oblique angle are constructed using a functional‐analytic, perturbative approach. Here, the main difficulties are the presence of continuous spectrum and the fact that small oblique angles appear as a singular perturbation in a traveling‐wave problem. We resolve the former difficulty using a farfield‐core decomposition and Fredholm theory in weighted spaces. The singular perturbation problem is resolved using preconditioners and boot‐strapping.

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u_{t} = - {(1 + Δ)}^{2} u + μ u - u^{3},

where

u = u (t, x, y) \in R

false(x, y false) \in {double-struckR}^{2}

t \in R

, subscripts denote partial derivatives, and

Δ u = u_{x x} + u_{y y}

.…”

Section: Introductionmentioning

confidence: 99%

Pattern‐forming fronts in a Swift–Hohenberg equation with directional quenching — parallel and oblique stripes

Goh

Scheel

2018

J. London Math. Soc.

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“…monolayer (right). Liesegang rings and helices formed through recurrent precipiation in tube-in-tube experiments Cu 2+ (aq) + CrO 2 4 (aq) → CuCrO4(s) in 1% agarose gel, schematic of relation to 2d-patterning, and numerical simuilations; reproduced with permission from [26], Copyright 2013, APS.…”

Section: Introductionmentioning

confidence: 99%

Phase Separation Patterns from Directional Quenching

Monteiro

Scheel

2017

J Nonlinear Sci

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We study the effect of directional quenching on patterns formed in simple bistable systems such as the Allen-Cahn and the Cahn-Hilliard equation on the plane. We model directional quenching as an externally triggered change in system parameters, changing the system from monostable to bistable across an interface. We are then interested in patterns forming in the bistable region, in particular as the trigger progresses and increases the bistable region. We find existence and non-existence results of single interfaces and striped patterns.

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“…Apparently, the thermal fluctuations choose from the possible patterns, which display a peaked probability distribution, [106] a behavior analogous to the stochastic mode selection observed in helical Liesegang systems. [107] E.…”

Section: Spiral Eutectic Dendritesmentioning

confidence: 99%

Phase-Field Modeling of Polycrystalline Solidification: From Needle Crystals to Spherulites—A Review

Gránásy

Rátkai

Szàllàs

et al. 2013

Metall Mater Trans A

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LÁ SZLÓ GRÁ NÁ SY, LÁ SZLÓ RÁ TKAI, ATTILA SZÁ LLÁ S, BÁ LINT KORBULY, GYULA I. TÓ TH, LÁ SZLÓ KÖ RNYEI, and TAMÁ S PUSZTAI Advances in the orientation-field-based phase-field (PF) models made in the past are reviewed. The models applied incorporate homogeneous and heterogeneous nucleation of growth centers and several mechanisms to form new grains at the perimeter of growing crystals, a phenomenon termed growth front nucleation. Examples for PF modeling of such complex polycrystalline structures are shown as impinging symmetric dendrites, polycrystalline growth forms (ranging from disordered dendrites to spherulitic patterns), and various eutectic structures, including spiraling two-phase dendrites. Simulations exploring possible control of solidification patterns in thin films via external fields, confined geometry, particle additives, scratching/piercing the films, etc. are also displayed. Advantages, problems, and possible solutions associated with quantitative PF simulations are discussed briefly.

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Probability of the Emergence of Helical Precipitation Patterns in the Wake of Reaction-Diffusion Fronts

Cited by 50 publications

References 30 publications

Pattern‐forming fronts in a Swift–Hohenberg equation with directional quenching — parallel and oblique stripes

Pattern‐forming fronts in a Swift–Hohenberg equation with directional quenching — parallel and oblique stripes

Phase Separation Patterns from Directional Quenching

Phase-Field Modeling of Polycrystalline Solidification: From Needle Crystals to Spherulites—A Review

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