Extraordinary stability of surfactant-free bubbles suspended in ultrasound

Droplet Pub Date : 2024-03-20 DOI:10.1002/dro2.119

Xiaoliang Ji, Wenxuan Zhong, Kangqi Liu, Yichen Jiang, Hongyue Chen, Wei Zhao, Duyang Zang

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Abstract

Gravity-induced drainage is one of the main destabilizing mechanisms for soap bubbles and foams. Here we show that solely through acoustic levitation without introducing any chemical stabilizers, liquid drainage in the bubble film can be completely inhibited, therefore leading to a significant enhancement of bubble lifetime by more than two orders of magnitude and enabling the bubble to survive puncturing by a needle. Based on sound simulation and force analysis, it has been found that acoustic radiation force, exerted on both the inner and outer surfaces of the levitated bubble, acts in opposite directions, thus providing a squeezing effect to the bubble film. The hydrostatic pressure that induces drainage has been balanced by the acoustic radiation pressure exerted on both sides of the film, which is at the origin of the sound stabilization mechanism. This study provides new insights into the interplay between sound and soap bubbles or films, thus stimulating a wide range of fundamental research concerning bubble films and expanding their applications in bio/chemical reactors.

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无表面活性剂气泡在超声波中悬浮的超强稳定性

重力引起的排液是肥皂泡和泡沫的主要失稳机制之一。在这里，我们展示了在不引入任何化学稳定剂的情况下，仅通过声学悬浮就能完全抑制气泡膜中的液体流失，从而显著延长气泡寿命两个数量级以上，并使气泡在针刺后仍能存活。根据声音模拟和受力分析发现，施加在悬浮气泡内外表面的声辐射力方向相反，从而对气泡膜产生挤压效应。引起排水的静水压力被施加在薄膜两侧的声辐射压力所平衡，这就是声稳定机制的起源。这项研究为了解声音与肥皂泡或薄膜之间的相互作用提供了新的视角，从而促进了有关气泡薄膜的广泛基础研究，并扩大了气泡薄膜在生物/化学反应器中的应用。

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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来源期刊

Droplet

CiteScore

6.60

自引率

0.00%

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