Directional Metastable Wetting Evolution of Droplets on Artificial Patterned Microcavity Surfaces

Xu, Wenshuai; Liu, Yu; Xiao, Bo-Ya; Jiang, Heng; Chen, Meng; Wang, Yuren

doi:10.1002/admi.202100174

Cited by 4 publications

(2 citation statements)

References 58 publications

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“…Typical examples are shown in refs. [99][100][101][102][103][104]. For instance, Liu et al [99] adopted a doubly reentrant structure that enables very low liquid-solid contact fraction which make the surface repel any liquid.…”

Section: Introductionmentioning

confidence: 99%

“…This result has potential application for the drag reduction of submerged surfaces. Xu et al [103] investigated the droplet spreading and wetting transition on the microcavitypatterned substrate. This work showed that the mesoscopic sequential Cassie-Wenzel transition leads to the macroscopic inward wetting transition from the periphery to the droplet center.…”

Section: Introductionmentioning

confidence: 99%

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Wetting Effect on Patterned Substrates

Wang

Nestler

2023

Advanced Materials

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A droplet deposited on a solid substrate leads to the wetting phenomenon. A natural observation is the lotus effect, known for its superhydrophobicity. This special feature is engendered by the structured microstructure of the lotus leaf, namely, surface heterogeneity, as explained by the quintessential Cassie-Wenzel theory (CWT). In this work, recent designs of functional substrates are overviewed based on the CWT via manipulating the contact area between the liquid and the solid substrate as well as the intrinsic Young's contact angle. Moreover, the limitation of the CWT is discussed. When the droplet size is comparable to the surface heterogeneity, anisotropic wetting morphology often appears, which is beyond the scope of the Cassie-Wenzel work. In this case, several recent studies addressing the anisotropic wetting effect on chemically and mechanically patterned substrates are elucidated. Surface designs for anisotropic wetting morphologies are summarized with respect to the shape and the arrangement of the surface heterogeneity, the droplet volume, the deposition position of the droplet, as well as the mean curvature of the surface heterogeneity. A thermodynamic interpretation for the wetting effect and the corresponding open questions are presented at the end.

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Section: Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Wetting Effect on Patterned Substrates

Wang

Nestler

2023

Advanced Materials

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Bio‐Inspired Differential Capillary Migration of Aqueous Liquid Metal Ink for Rapid Fabrication of High‐Precision Monolayer and Multilayer Circuits

Zhang

Gong

Chang

et al. 2023

Adv Funct Materials

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Manipulating liquid metal inks to create conductive microstructures has attracted widespread interest as liquid metal microstructures are turning into influential components in flexible electronics. However, it is challenging to prevent the issues with low precision, low efficiency, and residue caused by sedimentation, free diffusion, and the Marangoni effect. Inspired by the water transport in plants, the wetting-induced assembly method based on the differential capillary effect for liquid metal ink is created to realize the facile and rapid manufacture of liquid metal conductive microstructures. The single-micron accuracy circuits with a minimum of ≈4 µm straight lines are fabricated to a centimeter scale. This method can also be extended to the preparation of multilayer circuits (minimum 5 µm through hole). The resulting entirely flexible stretchable circuits make it possible to construct highly stretchable devices, such as flexible transparent conductors and stretching sensors. Transparent conductors exhibit excellent mechanical (maximum ≈750% tensile rupture limit) and optoelectronic properties (the transmittance reaches ≈87% and the sheet resistance is ≈0.5 Ω/□)|making them suitable for optically-clear electromagnetic shielding. This study offers a fresh and plain approach to solving the assembly problem of liquid metal inks, paving the way for the creation of flexible electronic devices

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Enhanced anti-icing and anticorrosion properties of nano-SiO2 composite superhydrophobic coating constructed by a large-scale micropillar array approach

Zhang

Gao

et al. 2023

Progress in Organic Coatings

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Directional Metastable Wetting Evolution of Droplets on Artificial Patterned Microcavity Surfaces

Cited by 4 publications

References 58 publications

Wetting Effect on Patterned Substrates

Wetting Effect on Patterned Substrates

Bio‐Inspired Differential Capillary Migration of Aqueous Liquid Metal Ink for Rapid Fabrication of High‐Precision Monolayer and Multilayer Circuits

Enhanced anti-icing and anticorrosion properties of nano-SiO2 composite superhydrophobic coating constructed by a large-scale micropillar array approach

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