Capillary-driven migration of droplets on conical fibers

arXiv - PHYS - Fluid Dynamics Pub Date : 2024-09-03 DOI:arxiv-2409.01822

Yixiao Mao, Chengxi Zhao, Kai Mu, Kai Li, Ting Si

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Abstract

A droplet placed on a hydrophilic conical fiber tends to move toward the end of larger radii due to capillary action. Experimental investigations are performed to explore the dynamics of droplets with varying viscosities and volumes on different fibers at the microscale. Droplets are found to accelerate initially and subsequently decelerate during migration. A dynamic model is developed to capture dynamics of the droplet migration, addressing the limitations of previous equilibrium-based scaling laws. Both experimental results and theoretical predictions indicate that droplets on more divergent fibers experience a longer acceleration phase. Additionally, gravitational effects are pronounced on fibers with small cone angles, exerting a substantial influence on droplet migration even below the capillary scale. Moreover, droplets move more slowly on dry fibers compared to those prewetted with the same liquid, primarily attributed to the increased friction. The experiments reveal the formation of a residual liquid film after droplet migration on dry fibers, leading to considerable volume loss in the droplets. To encompass the intricacies of migration on dry fibers, the model is refined to incorporate a higher friction coefficient and variable droplet volumes, providing a more comprehensive depiction of the underlying physics.

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锥形纤维上液滴的毛细管驱动迁移

由于毛细作用，置于亲水性锥形纤维上的液滴倾向于向较大半径的末端移动。实验研究探索了不同粘度和体积的液滴在不同纤维上的微观动态。研究发现液滴在迁移过程中初始加速，随后减速。为捕捉液滴迁移的动态过程，建立了一个动态模型，解决了以往基于平衡的缩放定律的局限性。实验结果和理论预测都表明，在发散性更强的纤维上的液滴会经历更长的加速阶段。此外，重力效应在锥角较小的纤维上非常明显，甚至在毛细尺度以下也会对液滴迁移产生重大影响。此外，与预先用相同液体润湿的纤维相比，液滴在干燥纤维上的移动速度更慢，这主要归因于摩擦力的增加。实验表明，液滴在干燥纤维上迁移后会形成一层残留液膜，导致液滴的体积大量损失。为了涵盖在干纤维上迁移的复杂性，对模型进行了改进，加入了更高的摩擦系数和可变液滴体积，从而更全面地描述了基本物理原理。

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 - PHYS - Fluid Dynamics

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