用于测量蒸发液滴瞬时接触角的数字全息显微镜

IF 2.3 3区 工程技术 Q2 ENGINEERING, MECHANICAL
Mohammad Mehdi Zamani Asl, Carlos A. Dorao, Alberto Giacomello, Maria Fernandino
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引用次数: 1

摘要

尽管液滴在衬底上蒸发的过程看起来很简单,但在蒸发过程中,液滴周边局部接触角的时间演变仍未完全了解。在这项工作中,使用数字全息显微镜在亚微米分辨率下捕捉液滴表面的时间演变。三维表面为确定瞬时三相接触线和沿整个液滴外围的局部视接触角提供了信息。视接触角由液滴表面的梯度计算,并定义为该函数沿液滴外围的最大斜率。然后将该方法应用于研究纳米升液滴在亲水性衬底上的扩散主导蒸发。对于非轴对称液滴,当接触线从一个钉住位置移动到另一个钉住位置时,沿接触线的接触角差异可达10 \(^\circ\)。数字全息显微镜使我们能够表征在蒸发过程中接触线的不规则运动和局部接触角的变化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Digital holographic microscopy for measurement of instantaneous contact angle of an evaporating droplet

Digital holographic microscopy for measurement of instantaneous contact angle of an evaporating droplet

Despite the apparent simplicity of the process of a droplet evaporating on a substrate, the temporal evolution of the local contact angle along the droplet periphery during the evaporation is still not fully understood. In this work, digital holographic microscopy is used for capturing the time evolution of the droplet surface at submicron resolution. The three-dimensional surface provides the information for determining the instantaneous three-phase contact line and the local apparent contact angle along the whole droplet periphery. The apparent contact angle is computed from the gradient of the droplet surface and defined as the maximum slope of this function along the periphery of the droplet. The method is then applied to study the diffusion dominated evaporation of nanoliter droplets on a hydrophilic substrate. For the case of a non-axisymmetric droplet, differences of up to 10\(^\circ\) in contact angle along the contact line were identified when the contact line went from one pinning position to another. Digital holographic microscopy allowed us to characterize the irregular motion of the contact line and local changes in contact angle during the evaporation process.

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来源期刊
Experiments in Fluids
Experiments in Fluids 工程技术-工程:机械
CiteScore
5.10
自引率
12.50%
发文量
157
审稿时长
3.8 months
期刊介绍: Experiments in Fluids examines the advancement, extension, and improvement of new techniques of flow measurement. The journal also publishes contributions that employ existing experimental techniques to gain an understanding of the underlying flow physics in the areas of turbulence, aerodynamics, hydrodynamics, convective heat transfer, combustion, turbomachinery, multi-phase flows, and chemical, biological and geological flows. In addition, readers will find papers that report on investigations combining experimental and analytical/numerical approaches.
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