内斯托克斯流中的流体动力粒子操纵原理

arXiv - PHYS - Fluid Dynamics Pub Date : 2024-09-13 DOI:arxiv-2409.08452

Xuchen Liu, Partha Kumar Das, Sascha Hilgenfeldt

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引用次数: 0

摘要

操纵小尺度颗粒穿过流线是微流体设备的基本任务。许多此类设备在雷诺数很低的情况下运行，并利用障碍物阵列使粒子偏转，但一直缺乏对相关流体力学效应的系统量化。在此，我们探索了另一种方法，即在涡流斯托克斯流中对无力球形粒子在流体动力粒子-壁相互作用下的位移进行严格建模。某些具有 Brokensymmetry 的莫法特涡流几何结构允许粒子在流线上发生系统偏转，从而导致粒子在法森场定点或极限循环处聚集。此外，粒子可被迫以指数方式接近通道壁，从而使短程力对粒子捕获（粘附）的定量预测成为可能。这种丰富的、与颗粒大小相关的行为表明，无惯性流在颗粒停留时间较长的设备中可广泛用于浓缩、分选或过滤。

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Principles of hydrodynamic particle manipulation in internal Stokes flow

Manipulation of small-scale particles across streamlines is the elementary task of microfluidic devices. Many such devices operate at very low Reynolds numbers and deflect particles using arrays of obstacles, but a systematic quantification of relevant hydrodynamic effects has been lacking. Here, we explore an alternate approach, rigorously modeling the displacement of force-free spherical particles in vortical Stokes flows under hydrodynamic particle-wall interaction. Certain Moffatt-like eddy geometries with broken symmetry allow for systematic deflection of particles across streamlines, leading to particle accumulation at either Faxen field fixed points or limit cycles. Moreover, particles can be forced onto trajectories approaching channel walls exponentially closely, making quantitative predictions of particle capture (sticking) by short-range forces possible. This rich, particle size-dependent behavior suggests the versatile use of inertial-less flow in devices with a long particle residence time for concentration, sorting, or filtering.

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arXiv - PHYS - Fluid Dynamics

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