Unidirectional rotation driven by random fluctuations

2011 21st International Conference on Noise and Fluctuations Pub Date : 2011-06-12 DOI:10.1109/ICNF.2011.5994359

Cheng-Hung Chang, T. Tsong

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引用次数: 1

Abstract

Ratchet effect might be responsible for the unidirectional movement of a couple of systems. The theoretical study of ratchet mechanism usually focuses on the particle or state properties on a prescribed ratchet potential. In contrast, this work starts with a real system and shows how one can manipulate the system setup to have a ratchet potential for the system state. The model consists of a rotor surrounded by several drivers on a 2D plane. Both the rotor and drivers are furnished with electric dipoles, through which they can interact with each other. During the rotational fluctuations of the driver dipoles between two states, the rotor may rotate unidirectionally, independent of whether the driver fluctuations are periodic or completely random. If the driver fluctuations come from the conformational change of certain protein subunits consuming ATP, the rotor behavior would be similar to the rotation of the central γ subunit of F0F1-ATPase in mitochondria. We compare the rotational properties of our model with that of the flashing ratchet and F0F1-ATPase. This model provides a feasible way for harvesting non-equilibrium energy from ambient noise, which could be used to design microscopic artificial machines.

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由随机波动驱动的单向旋转

棘轮效应可能是造成一些系统单向运动的原因。棘轮机制的理论研究通常集中在给定棘轮势的粒子或状态性质上。相比之下，这项工作从一个真实的系统开始，并展示了如何操纵系统设置以使系统状态具有棘轮势。该模型由一个在二维平面上被几个驱动器包围的转子组成。转子和驱动器都配有电偶极子，通过它们可以相互作用。在驱动偶极子在两种状态之间的旋转波动期间，转子可能单向旋转，而与驱动波动是周期性的还是完全随机的无关。如果驱动波动来自某些蛋白质亚基消耗ATP的构象变化，则转子行为将类似于线粒体中f0f1 -ATP酶中心γ亚基的旋转。我们将模型的旋转特性与闪烁棘轮和f0f1 - atp酶的旋转特性进行了比较。该模型为从环境噪声中获取非平衡能量提供了一种可行的方法，可用于微观人工机械的设计。

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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2011 21st International Conference on Noise and Fluctuations

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