Interface proliferation and the growth of labyrinths in a reaction-diffusion system

Goldstein, Raymond E.; Muraki, David J.; Petrich, Dean M.

doi:10.1103/physreve.53.3933

Cited by 115 publications

(111 citation statements)

References 74 publications

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“…For pure diblock copolymers, on the other hand, the region between micelletype structures must be filled with a homogeneous mixture, which may or may not be unstable. This paper's results have some qualitative similarity to a variety of systems that arise in the reaction-diffusion literature [13,21,27,45]. Pattern formation in variational models similar to ours has been studied by Muratov [26].…”

Section: Tionssupporting

confidence: 71%

Spatially Localized Structures in Diblock Copolymer Mixtures

Glasner¹

2010

SIAM J. Appl. Math.

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Abstract. Above the critical temperature for the order-disorder transition, diblock copolymer melts have been observed to exhibit localized structures that exist within the homogeneous mixture. This paper uses an Ohta-Kawasaki-type density functional to explore this regime. Spatially localized peak-shaped equilibria are studied in one, two, and three dimensions, corresponding to amphiphilic bilayers, cylindrical micelles, and spherical micelles, respectively. A combination of rigorous estimates, asymptotic analysis, and numerical computation is used to characterize solutions and the regime where they exist. The interaction of superpositions of these solutions is studied by a perturbation analysis and shows how steady multipeak configurations can be achieved. Evidence is found for a secondary bifurcation slightly below the spinodal instability threshold, beyond which self-replication phenomena are observed. Dynamics in two dimensions are also illustrated, suggesting other mechanisms for instability and growth.Key words. diblock copolymer, micelle, density functional theory, self-replication AMS subject classifications. 82D60, 35K55DOI. 10.1137/080743913 1. Introduction. Diblock copolymers are linear chain molecules composed of two distinct subchains. At low temperatures, repulsion between subchains can result in phase segregation, but macroscopic segregation cannot occur because of covalent bonding between subchains. This incomplete segregation can give rise to a variety of stable microstructures (see, e.g., [1,11,14,24]), which are typically characterized as spatially periodic patterns whose domain boundaries closely resemble minimal surfaces, such as spheres, cylinders, and gyroids [39].Outside of the regime where mixtures are unstable to spinodal decomposition, the situation for copolymers is more complicated than simple binary systems, such as those described by the Cahn-Hilliard theory [5]. In addition to a stable homogeneous state, there are other observed behaviors. Physical experiments have identified inhomogeneous states above the critical temperature, such as sparse arrangements of micellar structures [35,36,43] and anisotropic lamellar grains [15]. This paper seeks to investigate this regime and its dynamics using density functional theory and the corresponding gradient flow dynamics.Theoretical work on the disordered regime has focused on spherical micelles. Dormidontova and Lodge [9] use Semenov's strong segregation theory [37] to predict the concentration of micelle assemblies. Their theory predicts that the number of micelles increases rapidly below a "critical micelle temperature" (CMT), which is greater than the temperature at which a homogeneous mixture is spinodally unstable. Wang, Wang, and Yang [42] use self-consistent field theory calculations to find the density profile of individual spherical micelles and evaluate their excess free energy. They find that micelles exist (within the mean field approximation) for volume frac-

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Section: Tionssupporting

confidence: 71%

Spatially Localized Structures in Diblock Copolymer Mixtures

Glasner¹

2010

SIAM J. Appl. Math.

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“…This feature is reminiscent of spot splitting in the Gray-Scott reaction-diffusion system [33]. We also see the emergence of labyrinthine patterns from a bump that is unstable to mode 3 perturbations (figure 5), again a feature that has been observed in reaction-diffusion systems [34].…”

Section: Discussionsupporting

confidence: 57%

“…This technique is valid for arbitrary non-rotationally symmetric solutions, irrespective of their detailed shape. A potential tool to study the evolution of intricate structures such as the labyrinthine patterns seen here, is to formulate a description of the dynamics of the interface (where u(r, t) = h), along the lines described for reaction diffusion equations in [34].…”

Section: Discussionmentioning

confidence: 99%

Bumps and rings in a two-dimensional neural field: splitting and rotational instabilities

2007

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Abstract. In this paper, we consider instabilities of localized solutions in planar neural field firing rate models of Wilson-Cowan or Amari type. Importantly we show that angular perturbations can destabilize spatially localized solutions. For a scalar model with Heaviside firing rate function, we calculate symmetric one-bump and ring solutions explicitly and use an Evans function approach to predict the point of instability and the shapes of the dominant growing modes. Our predictions are shown to be in excellent agreement with direct numerical simulations. Moreover, beyond the instability our simulations demonstrate the emergence of multi-bump and labyrinthine patterns. With the addition of spike-frequency adaptation, numerical simulations of the resulting vector model show that it is possible for structures without rotational symmetry, and in particular multi-bumps, to undergo an instability to a rotating wave. We use a general argument, valid for smooth firing rate functions, to establish the conditions necessary to generate such a rotational instability. Numerical continuation of the rotating wave is used to quantify the emergent angular velocity as a bifurcation parameter is varied. Wave stability is found via the numerical evaluation of an associated eigenvalue problem.

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“…The two solutions agree within an accuracy of approximately 1% for the amplitude and 2% for the phase. In addition to the oscillatory instability spot solutions may also be unstable to transverse perturbations [35][36][37]. Numerical solutions of the fully twodimensional model (27) show that for the parameters of fronts leading to a labyrinthine pattern.…”

Section: B Uniform Curvaturementioning

confidence: 99%

Order parameter equations for front transitions: Planar and circular fronts

et al. 1997

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Near a parity breaking front bifurcation, small perturbations may reverse the propagation direction of fronts. Often this results in nonsteady asymptotic motion such as breathing and domain breakup. Exploiting the time scale differences of an activator-inhibitor model and the proximity to the front bifurcation, we derive equations of motion for planar and circular fronts. The equations involve a translational degree of freedom and an order parameter describing transitions between left and right propagating fronts. Perturbations, such as a space dependent advective field or uniform curvature (axisymmetric spots), couple these two degrees of freedom. In both cases this leads to a transition from stationary to oscillating fronts as the parity breaking bifurcation is approached. For axisymmetric spots, two additional dynamic behaviors are found: rebound and collapse.

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Interface proliferation and the growth of labyrinths in a reaction-diffusion system

Cited by 115 publications

References 74 publications

Spatially Localized Structures in Diblock Copolymer Mixtures

Spatially Localized Structures in Diblock Copolymer Mixtures

Bumps and rings in a two-dimensional neural field: splitting and rotational instabilities

Order parameter equations for front transitions: Planar and circular fronts

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