Localized states in passive and active phase-field-crystal models

IF 1.2 4区数学 Q2 MATHEMATICS, APPLIED IMA Journal of Applied Mathematics Pub Date : 2021-07-01 DOI:10.1093/imamat/hxab025

Max Philipp Holl;Andrew J Archer;Svetlana V Gurevich;Edgar Knobloch;Lukas Ophaus;Uwe Thiele

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引用次数: 12

Abstract

The passive conserved Swift–Hohenberg equation (or phase-field-crystal [PFC] model) describes gradient dynamics of a single-order parameter field related to density. It provides a simple microscopic description of the thermodynamic transition between liquid and crystalline states. In addition to spatially extended periodic structures, the model describes a large variety of steady spatially localized structures. In appropriate bifurcation diagrams the corresponding solution branches exhibit characteristic slanted homoclinic snaking. In an active PFC model, encoding for instance the active motion of self-propelled colloidal particles, the gradient dynamics structure is broken by a coupling between density and an additional polarization field. Then, resting and traveling localized states are found with transitions characterized by parity-breaking drift bifurcations. Here, we briefly review the snaking behavior of localized states in passive and active PFC models before discussing the bifurcation behavior of localized states in systems of (i) two coupled passive PFC models with common gradient dynamics, (ii) two coupled passive PFC models where the coupling breaks the gradient dynamics structure and (iii) a passive PFC model coupled to an active PFC model.

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被动和主动相场晶体模型中的局域态

被动守恒的Swift–Hohenberg方程（或相场晶体[PFC]模型）描述了与密度相关的一阶参数场的梯度动力学。它提供了一个简单的微观描述的热力学转变之间的液晶状态。除了空间扩展的周期性结构外，该模型还描述了各种稳定的空间局部化结构。在适当的分岔图中，相应的解分支表现出特征性的倾斜同宿蛇形。在主动PFC模型中，例如编码自推进胶体颗粒的主动运动，梯度动力学结构被密度和附加极化场之间的耦合打破。然后，发现了具有以宇称破坏漂移分叉为特征的跃迁的静止和行进局域态。在这里，我们简要回顾了无源和有源PFC模型中局部状态的蛇形行为，然后讨论了（i）具有公共梯度动力学的两个耦合无源PFC模型、（ii。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IMA Journal of Applied Mathematics 数学-应用数学

CiteScore

2.30

自引率

8.30%

发文量

审稿时长

24 months

期刊介绍： The IMA Journal of Applied Mathematics is a direct successor of the Journal of the Institute of Mathematics and its Applications which was started in 1965. It is an interdisciplinary journal that publishes research on mathematics arising in the physical sciences and engineering as well as suitable articles in the life sciences, social sciences, and finance. Submissions should address interesting and challenging mathematical problems arising in applications. A good balance between the development of the application(s) and the analysis is expected. Papers that either use established methods to address solved problems or that present analysis in the absence of applications will not be considered. The journal welcomes submissions in many research areas. Examples are: continuum mechanics materials science and elasticity, including boundary layer theory, combustion, complex flows and soft matter, electrohydrodynamics and magnetohydrodynamics, geophysical flows, granular flows, interfacial and free surface flows, vortex dynamics; elasticity theory; linear and nonlinear wave propagation, nonlinear optics and photonics; inverse problems; applied dynamical systems and nonlinear systems; mathematical physics; stochastic differential equations and stochastic dynamics; network science; industrial applications.