Continuous generation of confined bubbles: viscous effect on the gravito-capillary pinch off

arXiv - PHYS - Fluid Dynamics Pub Date : 2024-09-01 DOI:arxiv-2409.00637

Haruka Hitomi, Ko Okumura

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Abstract

We investigate continuous generation of bubbles from a bath of air in viscous liquid in a confined geometry. In our original setup, bubbles are spontaneously generated by virtue of buoyancy and a gate placed in the cell: the gate acts like an inverted funnel trapping air beneath it before continuously generating bubbles at the tip. The dynamics is characterized by the period of the bubble formation and the size of bubbles as a function of the amount of air under the gate. By analyzing the data obtained for various parameters, we successfully identified in a clear manner that the dynamics of the bubble formation is governed by dissipation in thin films whose thickness is determined by Derjaguin's law balanced by a gravitational energy change due to buoyancy, after examining numerous possibilities of dissipation, demonstrating the potential of scaling analysis even in extremely complex cases. Furthermore, we uncover a novel type of pinch-off condition, which convincingly explains the size of the bubble created: in the present case viscosity plays a vital role beyond the conventional mechanism of Tate in which gravity competes with capillarity, revealing a general mechanism of pinching-off at low Reynolds number. Accordingly, the present study significantly and fundamentally advance our knowledge of bubble generation and bubble pinch-off in a clear manner with the results relevant for a wide variety of applications in many fields. In particular, the present study demonstrates a new avenue in microfluidics for understanding physical principles by scaling up the system, without losing the characters of the flow at low Reynolds numbers.

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密闭气泡的连续生成：粘性对重力-毛细管挤压的影响

我们研究了在一个封闭的几何结构中，从粘性液体的空气浴中连续产生气泡的问题。在我们最初的设置中，气泡是凭借浮力和置于池中的闸门自发产生的：闸门就像一个倒置的漏斗，在其下方捕获空气，然后在顶端不断产生气泡。气泡形成的周期和气泡的大小与栅极下的空气量成函数关系，从而描述了气泡的动力学特征。通过分析各种参数获得的数据，我们成功地明确了气泡形成的动力学是由薄膜耗散所控制的，薄膜的厚度由德雅金定律决定，浮力导致的重力能量变化平衡了薄膜的厚度。此外，我们还发现了一种新型的掐断条件，令人信服地解释了所产生气泡的大小：在本例中，粘度发挥了重要作用，超越了重力与气泡竞争的传统塔特机制，揭示了低雷诺数掐断的一般机制。因此，本研究极大地从根本上推进了我们对气泡产生和气泡夹断的认识，其结果与许多领域的广泛应用息息相关。特别是，本研究通过扩大系统规模，为了解物理原理提供了一条新的微流体途径，同时又不失低雷诺数下的流动特性。

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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