Curvature Adjustable Liquid Transport on Anisotropic Microstructured Elastic Film

Li, Yan; Zhang, Qiuya; Wei, Xinyu; Li, Ké; Tian, Dongliang; Jiang, Lei

doi:10.1021/acsnano.3c00555

Cited by 7 publications

(4 citation statements)

References 44 publications

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“…Inspired by the “out of the silt without staining” property of lotus leaves in nature, superhydrophobic microstructure surfaces have remarkable application potential in self-cleaning, , anticorrosion, oil–water separation, − and droplet manipulation. , Currently, various methods have been proposed to construct low-adhesive and superhydrophobic surfaces, including templating, , laser, sol–gel process, electrostatic spinning, and electrochemical deposition . These methods are complex and rely on expensive equipment.…”

Section: Introductionmentioning

confidence: 99%

Multiscale Microflower Structured Superhydrophobic Surface via Electrostatic Air Spray

Chen

Liu

2023

Langmuir

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Superhydrophobic surfaces with microstructures and multifunctionality have attracted intense research interest. Herein, a multiscale microflower structured surface (MMSS) was successfully fabricated by electrostatic air spray. To systematically study the preparation process, the influences of different electrostatic voltages, solution ratios, soaking time, spray distances, and spray time on surface morphology and hydrophobicity were analyzed. The surface has good superhydrophobic properties with a water contact angle of 162.3°, which allows the surface to be selfcleaning and antifouling. The surface hydrophobicity can be maintained after various mechanical and chemical damages. To overcome the limitation that existing droplet manipulation relies on special materials and surfaces, a new and universal droplet transport method is presented to successfully perform nondestructive droplet manipulations, which relies on external forces and droplet deformation to drive droplets. Therefore, this paper represents a different approach from previous studies of superhydrophobic surfaces and provides a new way to achieve dynamic droplet manipulations. These results indicate that the multifunctional MMSS will be widely used in industrial droplet transportation and self-cleaning applications.

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Section: Introductionmentioning

confidence: 99%

Multiscale Microflower Structured Superhydrophobic Surface via Electrostatic Air Spray

Chen

Liu

2023

Langmuir

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“…Its surface nanostructure and water droplet transportation are shown in Figure 3b. Li et al [51] created a V-shaped array on the surface of an elastic material. By changing the curvature of the elastic film, the parameters of the V-shaped arrays can also be changed, which might lead to a difference in the wettability gradient.…”

Section: Sdwt Based On Wettability Gradientmentioning

confidence: 99%

Spontaneous Directional Transportation Surface of Water Droplet and Gas Bubble: A Review

Lu,

Yan,

Lin

et al. 2023

Applied Sciences

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The spontaneous directional transportation (SDT) of water and gas has functions such as efficient water collection, enhanced heat transfer, underwater drag reduction, and so on, having great application prospects in aerospace and navigation fields. Therefore, it is important to efficiently prepare spontaneous directional water droplet transportation (SDWT) surfaces and spontaneous directional gas bubble transportation (SDBT) surfaces and apply them in different fields. In recent years, researchers have used biological structures as the basis for their studies and have continued to analyze the SDT transport mechanism in depth, aiming to find more efficient transportation methods. In this review, we first summarize the important basic theories related to fluid transportation. Then, the related methods and the limitations corresponding to SDWT and SDBT are introduced and discussed. In addition, we review the applications of SDWT and SDBT. Finally, we highlight the challenges and future perspectives of SDWT and SDBT.

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“…The wettability of natural and artificial surfaces has received increasing attention in recent years. The wetting characteristics play an important role in a wide range of applications, such as high-energy-density batteries, , microscale liquid transport, , sweat sensors, and liquefaction . The wettability of CO 2 on artificial surfaces directly affects the efficiency of CO 2 condensation, evaporation, and heat transfer, which in turn limits the performance of CO 2 capture technologies , and transport of CO 2 -based working fluid in heat exchangers, heat pipes, vacuum chambers, and new thermodynamic cycles. , However, manipulating the CO 2 wettability and clearly elucidating its underlying mechanism remain challenging.…”

Section: Introductionmentioning

confidence: 99%

CO₂-philicity to CO₂-phobicity Transition on Smooth and Stochastic Rough Cu-like Substrate Surfaces

Yin,

Zhao,

Lin

2023

Langmuir

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Curvature Adjustable Liquid Transport on Anisotropic Microstructured Elastic Film

Cited by 7 publications

References 44 publications

Multiscale Microflower Structured Superhydrophobic Surface via Electrostatic Air Spray

Multiscale Microflower Structured Superhydrophobic Surface via Electrostatic Air Spray

Spontaneous Directional Transportation Surface of Water Droplet and Gas Bubble: A Review

CO₂-philicity to CO₂-phobicity Transition on Smooth and Stochastic Rough Cu-like Substrate Surfaces

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Curvature Adjustable Liquid Transport on Anisotropic Microstructured Elastic Film

Cited by 7 publications

References 44 publications

Multiscale Microflower Structured Superhydrophobic Surface via Electrostatic Air Spray

Multiscale Microflower Structured Superhydrophobic Surface via Electrostatic Air Spray

Spontaneous Directional Transportation Surface of Water Droplet and Gas Bubble: A Review

CO2-philicity to CO2-phobicity Transition on Smooth and Stochastic Rough Cu-like Substrate Surfaces

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Product

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About

CO₂-philicity to CO₂-phobicity Transition on Smooth and Stochastic Rough Cu-like Substrate Surfaces