Unidirectional transport of both wettable and nonwettable liquids on an asymmetrically concave structured surface

IF 6.2 3区 综合性期刊 Q1 Multidisciplinary Fundamental Research Pub Date : 2024-05-01 DOI:10.1016/j.fmre.2022.03.022
Zhongxue Tang , Kang Luan , Bojie Xu , Huan Liu
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Abstract

Unidirectional liquid transport (UDLT) has been widely used in various fields as an important process for transferring both mass and energy. However, UDLT driven by a structural gradient has been witnessed for a long time only in wettable liquids. For nonwettable liquids, UDLT can hardly proceed merely by a structural gradient. Herein, we propose an asymmetrically concave structured surface (AMC-surface), featuring tip-to-base periodically arranged pyramid-shaped concave structures with a certain degree of overlap, which enables the UDLT of both wettable and nonwettable liquids. For wettable liquids, the capillary force along each corner leads to the UDLT pointing toward the base side of the concave pyramid, while for nonwettable liquids, the UDLT is attributable to the static liquid pressure overwhelming the repulsive Laplace pressure induced by the asymmetric grooves and overlapping part. As a result, both wettable and nonwettable liquids transport spontaneously and unidirectionally on the AMC-surface with no energy input. Moreover, the concave structure endows good mechanical stability and can be easily prepared using a facile nail-punching approach over a large area. We also demonstrated its application in a continuous chemical reaction in a confined area. We envision that the unique UDLT behavior on the as-developed AMC-surface will shed new light on the programmable manipulation of various liquids.

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可湿性和非可湿性液体在不对称凹面结构表面上的单向传输
单向液体输运(UDLT)作为一种重要的质量和能量传递过程,已被广泛应用于各个领域。然而,由结构梯度驱动的 UDLT 长期以来只在可湿性液体中出现。对于非润湿液体,仅靠结构梯度很难实现 UDLT。在此,我们提出了一种非对称凹面结构表面(AMC-surface),其特点是顶端到底端周期性排列的金字塔形凹面结构具有一定程度的重叠,可实现可湿性液体和非可湿性液体的 UDLT。对于可湿性液体,沿每个角的毛细管力导致 UDLT 指向凹金字塔的底面,而对于非可湿性液体,UDLT 则归因于静态液体压力压倒由不对称凹槽和重叠部分引起的排斥性拉普拉斯压力。因此,无论是可湿性液体还是非可湿性液体,都能在 AMC 表面自发单向传输,无需输入能量。此外,凹面结构还具有良好的机械稳定性,而且可以用简便的打钉方法大面积制备。我们还展示了它在密闭区域内连续化学反应中的应用。我们设想,在所开发的 AMC 表面上的独特 UDLT 行为将为各种液体的可编程操作带来新的启示。
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来源期刊
Fundamental Research
Fundamental Research Multidisciplinary-Multidisciplinary
CiteScore
4.00
自引率
1.60%
发文量
294
审稿时长
79 days
期刊介绍:
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