Grain boundary pinning and glassy dynamics in stripe phases

Boyer, Denis; Viñals, Jorge

doi:10.1103/physreve.65.046119

Cited by 65 publications

(106 citation statements)

References 50 publications

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“…Factors affecting the measured exponent include external noise and the quantity used to characterize the domains. There is evidence that for small enough quench depths the growth exponent is 1/3 [8,10,13]. An open question is the connection between the simulations and the experiments with the diblock copolymer systems.…”

Section: Introductionmentioning

confidence: 99%

Dislocation dynamics in an anisotropic stripe pattern

2004

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The dynamics of dislocations confined to grain boundaries in a striped system are studied using electroconvection in the nematic liquid crystal N4. In electroconvection, a striped pattern of convection rolls forms for sufficiently high driving voltages. We consider the case of a rapid change in the voltage that takes the system from a uniform state to a state consisting of striped domains with two different wavevectors. The domains are separated by domain walls along one axis and a grain boundary of dislocations in the perpendicular direction. The pattern evolves through dislocation motion parallel to the domain walls. We report on features of the dislocation dynamics. The kinetics of the domain motion are quantified using three measures: dislocation density, average domain wall length, and the total domain wall length per area. All three quantities exhibit behavior consistent with power law evolution in time, with the defect density decaying as t −1/3 , the average domain wall length growing as t 1/3 , and the total domain wall length decaying as t −1/5 . The two different exponents are indicative of the anisotropic growth of domains in the system.

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Section: Introductionmentioning

confidence: 99%

Dislocation dynamics in an anisotropic stripe pattern

2004

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“…There are many reports in the literature showing metastable patterns and slow dynamics at low temperatures, which may be related with glassy physics [3,7,12,13,19,20]. Then it is important to assess the relevance of metastable states for the behavior of thermodynamic and dynamic functions.…”

Section: A Replica Technique For Uniformly Frustrated Systemsmentioning

confidence: 99%

“…A few experimental results quantifying the low temperature dynamics of quasi-twodimensional stripe forming systems have been reported [3,7]. Experimental and also computer simulation results [12,13] point to the presence of slow dynamics associated with the pinning of topological defects, which are the relevant excitations at low temperatures.…”

Section: Introductionmentioning

confidence: 99%

Glassy behavior of two-dimensional stripe-forming systems

2013

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We study two dimensional frustrated but non-disordered systems applying a replica approach to a stripe forming model with competing interactions. The phenomenology of the model is representative of several well known systems, like high-Tc superconductors and ultrathin ferromagnetic films, which have been the subject of intense research. We establish the existence of a glass transition to a non-ergodic regime accompanied by an exponential number of long lived metastable states, responsible for slow dynamics and non-equilibrium effects.

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“…If the system allows a Lyapunov functional this competition can be characterized in terms of the difference between the energies associated with the respective patterns. Unless the domain walls become pinned by the underlying pattern [49,50], it is expected that the final state arising from random initial conditions consists of the pattern with minimal energy [28,51].…”

Section: Competition Between Complex Patternsmentioning

confidence: 99%

Superlattice Patterns in the Complex Ginzburg–Landau Equation with Multiresonant Forcing

Conway¹,

Riecke

2009

SIAM J. Appl. Dyn. Syst.

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Motivated by the rich variety of complex patterns observed on the surface of fluid layers that are vibrated at multiple frequencies, we investigate the effect of such resonant forcing on systems undergoing a Hopf bifurcation to spatially homogeneous oscillations. We use an extension of the complex Ginzburg-Landau equation that systematically captures weak forcing functions with a spectrum consisting of frequencies close to the 1:1-, the 1:2-, and the 1:3-resonance. By slowly modulating the amplitude of the 1:2-forcing component we render the bifurcation to subharmonic patterns supercritical despite the quadratic interaction introduced by the 1:3-forcing. Our weakly nonlinear analysis shows that quite generally the forcing function can be tuned such that resonant triad interactions with weakly damped modes stabilize subharmonic patterns comprised of four or five Fourier modes, which are similar to quasi-patterns with 4-fold and 5-fold rotational symmetry, respectively. Using direct simulations of the extended complex Ginzburg-Landau equation we confirm our weakly nonlinear analysis. In simulations domains of different complex patterns compete with each other on a slow time scale. As expected from energy arguments, with increasing strength of the triad interaction the more complex patterns eventually win out against the simpler patterns. We characterize these ordering dynamics using the spectral entropy of the patterns. For system parameters reported for experiments on the oscillatory Belousov-Zhabotinsky reaction we explicitly show that the forcing parameters can be tuned such that 4-mode patterns are the preferred patterns.

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Grain boundary pinning and glassy dynamics in stripe phases

Cited by 65 publications

References 50 publications

Dislocation dynamics in an anisotropic stripe pattern

Dislocation dynamics in an anisotropic stripe pattern

Glassy behavior of two-dimensional stripe-forming systems

Superlattice Patterns in the Complex Ginzburg–Landau Equation with Multiresonant Forcing

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