受昆虫启发的呼吸界面:研究无涂层气体夹带微纹理表面在压力循环下的稳健性

Sankara Arunachalam, Muhammad Subkhi Sadullah, Himanshu Mishra
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引用次数: 0

摘要

在许多自然和工程应用中,都需要在水下表面夹带气穴或气泡。目前的气泡夹持技术依赖于全氟碳涂层,这限制了其可持续性。在此,我们研究了在静态和动态压力循环下,双复向腔体结构在实现气体夹持微纹理表面方面的功效。我们研究了正循环(1 个大气压)、负循环(1 个大气压)和正负循环在不同压力、斜率、循环间隔和水柱高度下对单个双复向腔内气体夹持稳定性的影响。值得注意的是,在压力循环作用下,被截留空气的命运属于以下两种情况之一:气泡(i)单调消耗(不稳定),(ii)保持无限稳定(稳定),或(iii)开始增长(气泡增长)。这种迄今为止尚未实现的丰富的水下气泡动力学应能指导无涂层技术的发展,并帮助我们了解呼吸空气的水生和海洋昆虫的奇特生活。桑卡拉-阿鲁纳恰拉姆及其同事探索了周期性压力对浸没在水中的微纹理表面内部空气命运的影响。这些发现为微纹理表面的设计和功能提供了指导,并为水下呼吸者的生存策略提供了启示。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Insect-inspired breathing interfaces: investigating robustness of coating-free gas entrapping microtextured surfaces under pressure cycles

Insect-inspired breathing interfaces: investigating robustness of coating-free gas entrapping microtextured surfaces under pressure cycles
Numerous natural and engineering scenarios necessitate the entrapment of air pockets or bubbles on submerged surfaces. Current technologies for bubble entrapment rely on perfluorocarbon coatings, limiting their sustainability. Herein, we investigated the efficacy of doubly reentrant cavity architecture towards realizing gas-entrapping microtextured surfaces under static and dynamic pressure cycling. The effects of positive (>1 atm), negative (<1 atm), and positive–negative cycles on the stability the gas entrapment inside individual doubly reentrant cavities were studied across a range of pressures, ramp rates, intercycle intervals, and water-column heights. Remarkably, the fate of the trapped air under pressure cycling fell into either of the following regimes: the bubble (i) monotonically depleted (unstable), (ii) remained indefinitely stable (stable), or (iii) started growing (bubble growth). This hitherto unrealized richness of underwater bubble dynamics should guide the development of coating-free technologies and help us understand the curious lives of air-breathing aquatic and marine insects. Sankara Arunachalam and colleagues explore the effects of cyclic pressure on the fate of air trapped inside microtextured surfaces submerged in water. The findings guide the design and function of gas-entrapping microtextured surfaces and offer insights into survival strategies of underwater breathers.
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