纳米尺度接触角滞后的特征:分子动力学洞察

Viktor Mandrolko, Guillaume Castanet, Sergii Burian, Yaroslav Grosu, Liudmyla Klochko, David Lacroix, Mykola Isaiev
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引用次数: 0

摘要

了解气体、液体和固体三相接触线的物理特性对许多应用都很重要。在宏观尺度上,三相接触线对外力作用的响应通常以接触角滞后为特征,文献中提出了多个模型对其进行描述。然而,在纳米尺度上仍需要更多有关此类模型应用的信息。本研究采用分子动力学方法研究了不同润湿状态下液滴在外力作用下的形状。此外,还建立了一个描述液滴形状的分析模型。通过该模型,我们可以准确评估后退和前进的润湿角。通过建模,我们发现毛细力和粘性力之间的相互作用对于描述纳米级液滴形状至关重要。在此框架下,我们指出了液体和蒸汽界面滚动运动的重要性。我们还证明,在毛细力与其他力相比最为显著的外力范围内,滞后现象可以用宏观尺度的 Cox-Voinov 模型很好地描述。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Features of the contact angle hysteresis at the nanoscale: A molecular dynamics insight
Understanding the physics of a three-phase contact line between gas, liquid, and solid is important for numerous applications. At the macroscale, the response of a three-phase contact line to an external force action is often characterized by a contact angle hysteresis, and several models are presented in the literature for its description. Yet, there is still a need for more information about such model applications at the nanoscale. In this study, a molecular dynamics approach was used to investigate the shape of a liquid droplet under an external force for different wetting regimes. In addition, an analytic model for describing the droplet shape was developed. It gives us the possibility to evaluate the receding and advancing wetting angle accurately. With our modeling, we found that the interplay between capillary forces and viscous forces is crucial to characterize the droplet shape at the nanoscale. In this frame, the importance of the rolling movement of the interface between liquid and vapor was pointed out. We also demonstrate that in the range of the external forces when capillary forces are most significant compared to others, hysteresis is well described by the macroscale Cox–Voinov model.
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