Self-organized escape processes of linear chains in nonlinear potentials

arXiv: Adaptation and Self-Organizing Systems Pub Date : 2014-06-04 DOI:10.1142/9789814590297_0022

Torsten Gross, D. Hennig, L. Schimansky-Geier

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引用次数: 2

Abstract

An enhancement of localized nonlinear modes in coupled systems gives rise to a novel type of escape process. We study a spatially one dimensional set-up consisting of a linearly coupled oscillator chain of $N$ mass-points situated in a metastable nonlinear potential. The Hamilton-dynamics exhibits breather solutions as a result of modulational instability of the phonon states. These breathers localize energy by freezing other parts of the chain. Eventually this localised part of the chain grows in amplitude until it overcomes the critical elongation characterized by the transition state. Doing so, the breathers ignite an escape by pulling the remaining chain over the barrier. Even if the formation of singular breathers is insufficient for an escape, coalescence of moving breathers can result in the required concentration of energy. Compared to a chain system with linear damping and thermal fluctuations the breathers help the chain to overcome the barriers faster in the case of low damping. With larger damping, the decreasing life time of the breathers effectively inhibits the escape process.

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非线性电位下线性链的自组织逃逸过程

耦合系统中局部非线性模态的增强产生了一种新型的逃逸过程。我们研究了一个由$N$质量点组成的线性耦合振子链组成的空间一维结构，该振子链位于亚稳态非线性势中。由于声子态的调制不稳定性，哈密顿动力学表现出呼吸解。这些呼吸者通过冷冻链的其他部分来定位能量。最终，链条的局部部分的振幅增长，直到它克服了以过渡态为特征的临界伸长。这样，呼吸者拉动剩下的链条越过屏障，点燃了逃生的火焰。即使单个呼吸者的形成不足以逃生，移动呼吸者的聚集也能产生所需的能量集中。与具有线性阻尼和热波动的链系统相比，在低阻尼的情况下，呼吸器有助于链更快地克服障碍。在较大的阻尼下，呼吸者寿命的缩短有效地抑制了逃逸过程。

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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arXiv: Adaptation and Self-Organizing Systems

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