Multiple Wetting–Dewetting States of a Water Droplet on Dual-Scale Hierarchical Structured Surfaces

Gao, Yurui; Liu, Yuan; Jiang, Jian; Zhu, Chongqin; Zuhlke, Craig; Alexander, Dennis R.; Francisco, Joseph S.; Zeng, Xiao Cheng

doi:10.1021/jacsau.1c00183

Cited by 5 publications

(2 citation statements)

References 53 publications

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“…Superhydrophobic surfaces find wide applications including anti-icing [1], anti-frosting [2], water collection [3], oil-water separation [4], drag-reducing [5,6], self-cleaning [7], prevention of corrosion [8,9], solar cells [10,11], and light-emitting diodes [12,13], just to name a few. Over the years, the wettability of a pillared surface has been extensively studied both experimentally [3] and theoretically [14][15][16][17]. Researchers have explored surfaces texturized with pillars that are diverse in shape and size.…”

Section: Introductionmentioning

confidence: 99%

Molecular Simulation Study on the Wettability of a Surface Texturized with Hierarchical Pillars

et al. 2023

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By using molecular dynamics simulation, we investigate the wettability of a surface texturized with a periodic array of hierarchical pillars. By varying the height and spacing of the minor pillars on top of major pillars, we investigate the wetting transition from the Cassie–Baxter (CB) to Wenzel (WZ) states. We uncover the molecular structures and free energies of the transition and meta-stable states existing between the CB and WZ states. The relatively tall and dense minor pillars greatly enhance the hydrophobicity of a pillared surface, in that, the CB-to-WZ transition requires an increased activation energy and the contact angle of a water droplet on such a surface is significantly larger.

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Section: Introductionmentioning

confidence: 99%

Molecular Simulation Study on the Wettability of a Surface Texturized with Hierarchical Pillars

et al. 2023

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“…Notably, even if the impacting droplet might invade the microtroughs when the water hammer pressure exceeds the antiwetting capillary pressure, they can still bounce off due to the maintenance of the nano-Cassie state (Section S3, Figure S10). ,, Additionally, this multiscale nonwetting state is of great significance for anti-icing properties in an icy environment. As shown in Figures b, c, and S11, the condensation droplets/frost on the STPL surface at ∼−10° can be removed by water droplets or jet impact without liquid adhesion, showing excellent microscopical antiwetting performance (Movies S2, S3).…”

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confidence: 99%

Holistic Anti/Dewetting Design of Anti/Deicing Superhydrophobic Surfaces (ADISS)

Meng,

Xing,

et al. 2024

ACS Materials Lett.

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Anti/deicing superhydrophobic surfaces (ADISS) exhibit appealing capabilities of shedding water and delaying icing through the nonwetting Cassie−Baxter (C−B) state, whose maintenance should be a prerequisite for the practical applications of ADISS. However, the C−B state often suffers from inevitable degradation, while its recovery encounters significant challenges. Therefore, holistic antiwetting/dewetting designs deserve more attention to deal with multiscale water exposure of ADISS involving multifactorial interactions in time and space. Herein, three criteria were proposed for the design of nonwetting ADISS: high intrinsic contact angle, fine nanoscale structures, and appropriate spatial distribution of micro/nanostructures. By optimized air spraying, the target nanoengineered surfaces were constructed with a stable nano-Cassie state and improved anti-icing and antifrosting properties. Moreover, the dewetting ability to achieve the recovery of the C−B state was demonstrated, based on which a novel deicing mechanism involving coalescence-induced ice detachment has been revealed. This design method of ADISS is holistic and easy to execute, thus, having practical value in engineering applications.

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Excellent hydrophobicity and high mobility of condensate droplets on hierarchical nanostructured surfaces: Insights from MD simulations

Qiang,

Lan,

Liu

et al. 2024

Journal of Molecular Liquids

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Multiple Wetting–Dewetting States of a Water Droplet on Dual-Scale Hierarchical Structured Surfaces

Cited by 5 publications

References 53 publications

Molecular Simulation Study on the Wettability of a Surface Texturized with Hierarchical Pillars

Molecular Simulation Study on the Wettability of a Surface Texturized with Hierarchical Pillars

Holistic Anti/Dewetting Design of Anti/Deicing Superhydrophobic Surfaces (ADISS)

Excellent hydrophobicity and high mobility of condensate droplets on hierarchical nanostructured surfaces: Insights from MD simulations

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