通过非平衡波动引起的粗糙度诱导输运增强

IF 5.6 1区数学 Q1 MATHEMATICS, INTERDISCIPLINARY APPLICATIONS

Chaos Solitons & Fractals Pub Date : 2025-10-07 DOI:10.1016/j.chaos.2025.117366

Li-Ming Fan, Ming-Gen Li, Tian-Fu Gao, Jing-Dong Bao

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引用次数: 0

摘要

理解和控制远离热平衡的系统中的输运是物理学、生物学和纳米技术的基本目标。该领域的一个典型原则是，景观粗糙度几乎普遍作为阻碍粒子运动和抑制定向传输的有害因素。在这里，我们通过证明由离散非平衡散粒噪声驱动的粒子，工程景观粗糙度可以不作为耗散障碍，而是作为增强定向传输的建设性引擎来挑战这种范式。这种增强使粒子的速度大大超过了自由粒子的极限——即在没有势的情况下，单纯由驱动产生的平均速度。我们将这种效应追溯到一种新的动态机制，我们称之为单向滑动抑制。由于势的全局不对称性和局部粗糙度之间的协同作用，该机制通过选择性地抑制向后的粒子滑动有效地纠正了非平衡波动。这些发现建立了通过工程无序控制传输的新原理，为启发设计更高效的纳米机器人开辟了新的途径，并为颗粒分离装置提供了新的原理。

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Roughness-induced transport enhancement via non-equilibrium fluctuations

Understanding and controlling transport in systems far from thermal equilibrium is a fundamental goal in physics, biology, and nanotechnology. A canonical principle in this field is that landscape roughness almost universally acts as a detrimental factor that impedes particle motion and suppresses directed transport. Here, we challenge this paradigm by demonstrating that for particles driven by discrete non-equilibrium shot noise, engineered landscape roughness can act not as a dissipative obstacle, but as a constructive engine that enhances directed transport. This enhancement drives the particle to a velocity that significantly exceeds the free-particle limit-the average velocity resulting purely from the drive in the absence of a potential. We trace this effect to a novel dynamic mechanism we term unidirectional slide inhibition. Arising from a synergy between the potential’s global asymmetry and its local roughness, this mechanism effectively rectifies non-equilibrium fluctuations by selectively suppressing backward particle sliding. These findings establish a new principle for controlling transport via engineered disorder, opening new avenues for inspiring the design of more efficient nano-robots and providing new principles for particle-separation devices.

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来源期刊

Chaos Solitons & Fractals 物理-数学跨学科应用

CiteScore

13.20

自引率

10.30%

发文量

1087

审稿时长

9 months

期刊介绍： Chaos, Solitons & Fractals strives to establish itself as a premier journal in the interdisciplinary realm of Nonlinear Science, Non-equilibrium, and Complex Phenomena. It welcomes submissions covering a broad spectrum of topics within this field, including dynamics, non-equilibrium processes in physics, chemistry, and geophysics, complex matter and networks, mathematical models, computational biology, applications to quantum and mesoscopic phenomena, fluctuations and random processes, self-organization, and social phenomena.