Quantifying droplet–solid friction using an atomic force microscope

Droplet Pub Date : 2024-02-20 DOI:10.1002/dro2.107

Xue Qi Koh, Calvin Thenarianto, Ville Jokinen, Dan Daniel

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Abstract

Controlling the wetting and spreading of microdroplets is key to technologies such as microfluidics, ink-jet printing, and surface coating. Contact angle goniometry is commonly used to characterize surface wetting by droplets, but the technique is ill-suited for high contact angles close to $180 °$ . Here, we attach a micrometric-sized droplet to an atomic force microscope cantilever to directly quantify droplet–solid friction on different surfaces (superhydrophobic and underwater superoleophobic) with sub-nanonewton force resolutions. We demonstrate the versatility of our approach by performing friction measurements using different liquids (water and oil droplets) and under different ambient environments (in air and underwater). Finally, we show that underwater superoleophobic surfaces can be qualitatively different from superhydrophobic surfaces: droplet–solid friction is highly sensitive to droplet speeds for the former but not for the latter surface.

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利用原子力显微镜量化液滴与固体之间的摩擦力

控制微液滴的润湿和扩散是微流控、喷墨打印和表面涂层等技术的关键。接触角测角法通常用于表征液滴对表面的润湿，但该技术并不适合接近......的高接触角。在这里，我们将微米大小的液滴附着在原子力显微镜悬臂上，以亚纳牛顿力分辨率直接量化不同表面（超疏水性和水下超疏水性）上的液滴-固体摩擦力。我们使用不同的液体（水滴和油滴）和在不同的环境（空气中和水下）下进行摩擦测量，证明了我们方法的多功能性。最后，我们展示了水下超疏水表面与超疏水表面的本质区别：前者的液滴-固体摩擦对液滴速度高度敏感，而后者的液滴-固体摩擦对液滴速度不敏感。

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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