Crystallization kinetics and self-induced pinning in cellular patterns

Igor S. Aranson; Boris A. Malomed; Len M. Pismen; Lev S. Tsimring

doi:10.1103/PhysRevE.62.R5

Crystallization kinetics and self-induced pinning in cellular patterns

Igor S. Aranson, Boris A. Malomed, Len M. Pismen, Lev S. Tsimring

School of Electrical Engineering

Research output: Contribution to journal › Article › peer-review

32 Scopus citations

Abstract

The aspect of pattern formation in nonequilibrium media such as self-induced pinning and stick-and-slip motion of the interphase boundary, as a particular kind of crystallization or melting is modelled by the Swift-Hohenberg (SH) equation. Within the SH model, the front propagation between cellular and uniform states can be evaluated by periodic nucleation events initiated by a violent growth of the localized zero-eigenvalue mode of the corresponding linear problem. An evolution equation for this mode is estimated using asymptotic analysis wherein the time interval between nucleation events and the front speed are estimated. The creep velocity exponent of `thermally activated' front propagation beyond the pinning threshold is derived.

Original language	English
Pages (from-to)	R5-R8
Journal	Physical Review E - Statistical Physics, Plasmas, Fluids, and Related Interdisciplinary Topics
Volume	62
Issue number	1 A
DOIs	https://doi.org/10.1103/PhysRevE.62.R5
State	Published - Jul 2000

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abstract = "The aspect of pattern formation in nonequilibrium media such as self-induced pinning and stick-and-slip motion of the interphase boundary, as a particular kind of crystallization or melting is modelled by the Swift-Hohenberg (SH) equation. Within the SH model, the front propagation between cellular and uniform states can be evaluated by periodic nucleation events initiated by a violent growth of the localized zero-eigenvalue mode of the corresponding linear problem. An evolution equation for this mode is estimated using asymptotic analysis wherein the time interval between nucleation events and the front speed are estimated. The creep velocity exponent of `thermally activated' front propagation beyond the pinning threshold is derived.",

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Crystallization kinetics and self-induced pinning in cellular patterns

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