非对称周期通道中可变形自推进粒子的定向输运

None Guo Rui-Xue, None Ai Bao-Quan
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引用次数: 0

摘要

分子马达是生物体内能有效地将化学能转化为机械能的装置,目前对分子马达的研究处于生物学和物理学的前沿。其引导运动的动态过程,以及在细胞内物质运输中所起的关键作用,引起了许多研究者的极大兴趣。理论和实验研究使得对这些分子马达的运动特性进行了详细的研究。布朗棘轮模型很重要。它提供了一个非平衡系统的例子,通过利用时间或空间不对称将热波动转化为引导输运。这一机制在物理学、生物学和纳米技术等领域得到了广泛的探索和研究。对各种棘轮的研究和最佳条件的确定有助于更深入地理解引导布朗粒子输运。以前对棘轮系统的研究主要集中在不对称结构中不同类型粒子(活性、极性和手性)的整流运动。然而,可变形粒子在不对称通道中的输运尚未得到研究。软材料系统中的颗粒,如细胞单层、组织、泡沫和乳液,经常是可变形的。这些软颗粒的形状变形对系统的动力学行为有显著影响。因此,理解这些可变形粒子在受限结构中的导向输运是至关重要的。为了更清楚地解释这个问题,我们数值模拟了二维、周期性、不对称通道中活动的、可变形粒子的导向输运。我们确定了影响这些粒子在受限结构内传输的因素。可变形粒子模型的主要特征是粒子的形状具有多自由度。对于主动可变形粒子,自推进速度破坏热力学平衡,导致空间不对称条件下的引导输运。我们的发现表明,粒子的运动方向完全由通道的不对称参数决定,它倾向于被吸引到增加的稳定性。提高粒子自推进速度和粒子柔软度有利于棘轮运输。当<i>v</i><sub>0</sub>[j]大时,颗粒的拉伸效应更加明显,颗粒的软化明显增强了定向输运。相反,密度和旋转扩散的增加会减缓颗粒整流。增加的密度会阻碍颗粒,使通道通过更加困难。升高的旋转扩散减少了持续时间,挑战了粒子通过通道的转变。在密度不变的情况下,更多的颗粒也会促进整流。这些研究结果为研究受限结构中可变形颗粒的输运行为提供了有价值的见解。它们还为软物质领域的应用实验提供了重要的理论支持。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Directed Transport of Deformable Self-propulsion Particles in an Asymmetric Periodic Channel
Molecular motor can effectively convert chemical energy into mechanical energy in living organisms, and its research is currently at the forefront of study in biology and physics . The dynamic process of its guided movement, along with the crucial role they play in intra-cellular material transport, has significantly aroused the interest of many researchers. Theoretical and experimental researches have allowed detailed examinations of the motion attributes of these molecular motors. The Brownian ratchet model important. It provides an illustration of a non-equilibrium system that transforms thermal fluctuation into guided transport by utilizing temporal or spatial asymmetry. The mechanism has been extensively explored and studied across fields including physics, biology and nanotechnology. Investigations into a variety of ratchets and identification of optimum conditions contribute to a deeper understanding of guided Brownian particle transport.Preceding studies on ratchet systems largely concentrated on the rectification motions of diverse types of particles – active, polar and chiral – in asymmetric structures. However, the transport of deformable particles in asymmetric channel has not been examined relatively unexamined. Particles in soft material systems such as cell monolayer, tissue, foam, and emulsion are frequently deformable. The shape deformation of these soft particles significantly affects the system's dynamic behavior. Thus, understanding the guided transport of these deformable particles within a confined structure is crucial.In order to explain this problem more clearlyt, we numerically simulate the guided transportation of active, deformable particles within a two-dimensional, periodic, asymmetric channel. We identify the factors that influence the transport of these particles within a confined structure. The main feature of the deformable particle model is that the particle’s shape is characterized by multiple degree of freedom. For active deformable particles, self-propulsion speed disrupts thermodynamic equilibrium, leading to guided transport in spatially asymmetric condition. Our findings demonstrate that a particle's direction of movement is entirely determined by the channel's asymmetric parameter, and it tends to be attracted towards increased stability. Augmenting particle self-propulsion speed and particle softness can facilitate ratchet transport. When v0[请说明这是什么物理量] is large, the particle’s tensile effect becomes more apparent, and particle softening significantly enhances directed transport. In contrast, an increase in density and rotational diffusion can slow particle rectification. Increased density can obstruct particles, making channel passage more difficult. Elevated rotational diffusion reduces persistence length, challenging particle transition through channels. With constant density, a greater number of particles will also encourage rectification. These research findings offer a valuable insight into the transportation behaviors of deformable particles in a confined structure. They also deliver crucial theoretical support for applicable experiments in the field of soft matter.
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